Sensor module, electronic apparatus, and vehicle

ABSTRACT

A sensor module includes a first sensor device that outputs first measurement data from a first measurement circuit receiving a signal from a first sensor element and performing a measurement process, a second sensor device that outputs a second measurement circuit receiving a signal from a second sensor element and performing a measurement process, and a microcontroller that receives the first measurement data and the second measurement data, in which the first sensor device includes a first terminal that is used for input of an external synchronization signal or a synchronization signal which is a signal based on the external synchronization signal, and input or output of a communication signal, and the second sensor device includes a second terminal that is used for input of the synchronization signal, and input or output of the communication signal.

The present application is based on, and claims priority from JP Application Serial Number 2018-142394, filed Jul. 30, 2018, and is a continuation from U.S. application Ser. No. 16/524,481, filed Jul. 29, 2019, the disclosures of which are hereby incorporated by reference herein in their entirety.

BACKGROUND 1. Technical Field

The present disclosure relates to a sensor module, an electronic apparatus, and a vehicle.

2. Related Art

As a technique of making reading of measurement data in a host device efficient, there is the related art disclosed in JP-A-2015-114810. In this related art, in a case where common addresses with a plurality of measurement devices connected to a host device as common destinations are designated, and a read command is issued, an interface portion transmits measurement data to the host device in a data transmission order.

Meanwhile, in recent years, the demand for high accuracy of a sensor module used to measure information of a measurement target object has been increased. In order to measure information of a measurement target object based on measurement data from a plurality of sensor devices mounted on a sensor module, the pieces of measurement data are required to be synchronized with each other, or the time at which the measurement data is acquired is required to be clarified.

However, in the related art, a timing at which measurement data is actually updated is not taken into consideration in a plurality of sensor devices. Thus, there is a problem in that it is not taken into consideration at which timing measurement data is to be transmitted to a microcontroller mounted on the sensor module.

SUMMARY

A sensor module according to an aspect of the present disclosure includes a first sensor device that includes a first sensor element, a first measurement circuit receiving a signal from the first sensor element and performing a measurement process, and a first interface circuit outputting first measurement data from the first measurement circuit; a second sensor device that includes a second sensor element, a second measurement circuit receiving a signal from the second sensor element and performing a measurement process, and a second interface circuit outputting second measurement data from the second measurement circuit; and a microcontroller that receives the first measurement data from the first sensor device and the second measurement data from the second sensor device, in which the first sensor device includes a first terminal that is used for input of an external synchronization signal or a synchronization signal which is a signal based on the external synchronization signal, and input or output of a communication signal, and the second sensor device includes a second terminal that is used for input of the synchronization signal, and input or output of the communication signal.

The sensor module according to the aspect may further include a selection circuit that selects whether or not the synchronization signal is to be input to the first interface circuit and the second interface circuit based on a signal from the microcontroller.

In the sensor module according to the aspect, the first interface circuit may output the first measurement data to the microcontroller based on the synchronization signal, and the second interface circuit may output the second measurement data to the microcontroller based on the synchronization signal.

In the sensor module according to the aspect, the first interface circuit may output the first measurement data which is fetched from the first measurement circuit at a synchronization timing of the synchronization signal, to the microcontroller, and the second interface circuit may output the second measurement data which is fetched from the second measurement circuit at the synchronization timing of the synchronization signal, to the microcontroller.

In the sensor module according to the aspect, the microcontroller may include a third terminal that is used for input of the synchronization signal, and input or output of the communication signal.

In the sensor module according to the aspect, the microcontroller may include an interruption controller, and the external synchronization signal may be input to the interruption controller.

In the sensor module according to the aspect, the microcontroller may include a processing circuit, and the processing circuit performs a process of issuing a command for acquiring the first measurement data from the first sensor device and the second measurement data from the second sensor device, with the external synchronization signal as an interruption cause.

In the sensor module according to the aspect, the microcontroller may include a signal processing circuit that performs a digital signal process on the first measurement data from the first sensor device and the second measurement data from the second sensor device, and the signal processing circuit may perform the digital signal process every synchronization timing of the external synchronization signal.

In the sensor module according to the aspect, when the digital signal process is completed, the microcontroller may output a signal indicating completion of the digital signal process to the outside.

In the sensor module according to the aspect, the microcontroller may further include a host interface circuit, and the microcontroller may output the first measurement data and the second measurement data having undergone the digital signal process to the outside via the host interface circuit.

In the sensor module according to the aspect, the external synchronization signal may be a signal generated based on a time reference signal.

In the sensor module according to the aspect, the time reference signal may be a signal acquired from a satellite positioning system.

A sensor module according to another aspect of the present disclosure includes a first sensor element; a second sensor element; a measurement circuit that receives signals from the first sensor element and the second sensor element, and performs a measurement process; an interface circuit that outputs measurement data from the measurement circuit; and a microcontroller that receives the measurement data, in which the microcontroller selects one of input of an external synchronization signal or a synchronization signal which is a signal based on the external synchronization signal to the interface circuit, and input or output of a communication signal to or from the interface circuit.

An electronic apparatus according to still another aspect of the present disclosure includes the sensor module according to the aspect; and a processor that performs a process based on an output signal from the sensor module.

A vehicle according to still another aspect of the present disclosure includes the sensor module according to the aspect; and a control device that controls a posture of a vehicle based on posture information of the vehicle obtained through a process based on an output signal from the sensor module.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram illustrating a configuration example of a sensor module of the present embodiment.

FIG. 2 is a diagram illustrating a configuration example of a microcontroller.

FIG. 3 is a diagram illustrating another configuration example of the microcontroller.

FIG. 4 is a signal waveform diagram illustrating an operation of the sensor module.

FIG. 5 is a diagram illustrating a configuration example of the sensor device.

FIG. 6 is a flowchart illustrating an operation of the microcontroller.

FIG. 7 is a diagram illustrating a configuration example of the sensor module measuring angular velocity and acceleration.

FIG. 8 is a diagram illustrating a configuration example of the sensor module measuring angular velocity and acceleration.

FIG. 9 is a diagram illustrating a signal waveform example in a first digital interface bus.

FIG. 10 is a diagram illustrating a signal waveform example in a second digital interface bus.

FIG. 11 is a diagram illustrating a signal waveform example in the first digital interface bus.

FIG. 12 is a diagram illustrating a signal waveform example in the second digital interface bus.

FIG. 13 is a diagram illustrating another configuration example of the sensor module of the present embodiment.

FIG. 14 is a diagram illustrating a configuration example of a measurement system including the sensor module.

FIG. 15 is an exploded perspective view of the sensor module.

FIG. 16 is a diagram illustrating a configuration example of an angular velocity sensor device.

FIG. 17 is a block diagram illustrating a configuration example of an electronic apparatus of the present embodiment.

FIG. 18 is a plan view illustrating a wristwatch type activity meter which is a portable electronic apparatus.

FIG. 19 is a block diagram illustrating a configuration example of the wristwatch type activity meter which is a portable electronic apparatus.

FIG. 20 is a diagram illustrating an example of a vehicle according to the present embodiment.

FIG. 21 is a block diagram illustrating a configuration example of the vehicle.

FIG. 22 is a diagram illustrating an example of another vehicle of the present embodiment.

FIG. 23 is a block diagram illustrating a configuration example of the vehicle.

DESCRIPTION OF EXEMPLARY EMBODIMENTS

Hereinafter, a preferred embodiment of the present disclosure will be described in detail. The embodiments described below do not improperly limit the content of the present disclosure disclosed in the appended claims. All configurations described below are not essential to the present disclosure.

1. Configuration Example of Sensor Module

FIG. 1 illustrates a configuration example of a sensor module 10 of the present embodiment. The sensor module 10 is a physical quantity measurement module configured with a plurality of sensor devices, and a sensor system or a sensor unit is implemented by the sensor module 10.

The sensor module 10 in FIG. 1 includes a first sensor device 20X, a second sensor device 20Y, a microcontroller 80, and a selection circuit 11. A configuration of the sensor module 10 is not limited to the configuration illustrated in FIG. 1 , and may be variously modified by omitting some constituent elements or adding other constituent elements. For example, FIG. 1 illustrates an exemplary case where the number of sensor devices is two, but the number of sensor devices may be three or more. For example, the sensor module 10 of the present embodiment may include a first sensor device to an n-th sensor device (where n is an integer of 2 or greater).

The first sensor device 20X includes a first sensor element 50X, a first measurement circuit 60X which receives a signal from the first sensor element 50X and performs a measurement process, and a first interface circuit 70X which outputs first measurement data SD1 from the first measurement circuit 60X. The first sensor device 20X is a device in which an integrated circuit device including the first sensor element 50X, the first measurement circuit 60X, and the first interface circuit 70X is accommodated in a package. The integrated circuit device is an IC chip implemented by semiconductor. The first sensor device 20X has a terminal TCS1, a terminal TCK1, a terminal TDI1, and a terminal TDO1 which are external connection terminals provided on, for example, a package.

The second sensor device 20Y includes a second sensor element 50Y, a second measurement circuit 60Y which receives a signal from the second sensor element 50Y and performs a measurement process, and a second interface circuit 70Y which outputs second measurement data SD2 from the second measurement circuit 60Y. The second sensor device 20Y is a device in which an integrated circuit device including the second sensor element 50Y, the second measurement circuit 60Y, and the second interface circuit 70Y is accommodated in a package. The second sensor device 20Y has a terminal TCS2, a terminal TCK2, a terminal TDI2, and a terminal TDO2 which are external connection terminals provided on, for example, a package.

In a case where the number of sensor devices is three or more, and an n-th sensor device is provided, the n-th sensor device may include an n-th sensor element, an n-th measurement circuit which receives a signal from the n-th sensor element and performs a measurement process, and an n-th interface circuit which outputs n-th measurement data from the n-th measurement circuit.

The first sensor element 50X and the second sensor element 50Y are sensor elements measuring a physical quantity, and may be said to be physical quantity transducers. The physical quantity is, for example, angular velocity, acceleration, angular acceleration, velocity, a distance, pressure, sound pressure, or a quantity of magnetism. The first sensor element 50X and the second sensor element 50Y measure different physical quantities. For example, in a case of angular velocity, the first sensor element 50X measures an angular velocity about a first axis, and the second sensor element 50Y measures an angular velocity about a second axis. For example, in a case of acceleration, the first sensor element 50X measures an acceleration in a direction of the first axis, and the second sensor element 50Y measures an acceleration in a direction of the second axis. Alternatively, the first sensor element 50X may measure a first physical quantity of angular velocity, acceleration, angular acceleration, velocity, a distance, pressure, or a quantity of magnetism which is a physical quantity, and the second sensor element 50Y may measure a second physical quantity which is different from the first physical quantity. As an example, the first sensor element 50X measures angular velocity, and the second sensor element 50Y measures acceleration.

Each of the first measurement circuit 60X and the second measurement circuit 60Y may include an analog circuit and an A/D conversion circuit which converts an analog signal from the analog circuit into digital data. The analog circuit may include an amplification circuit which amplifies a signal from the sensor element, a detecting circuit such as a synchronous detecting circuit, a gain adjustment circuit, or an offset adjustment circuit. The A/D conversion circuit outputs digital measurement data to the first interface circuit 70X. As A/D conversion types of the A/D conversion circuit, a successive comparison type, a delta sigma type, a flash type, a pipeline type, or a double integral type may be employed.

Each of the first interface circuit 70X and the second interface circuit 70Y is, for example, a circuit which performs a digital interface process, and performs, for example, transmission or reception of serial data. In the present embodiment, each of the first interface circuit 70X and the second interface circuit 70Y performs an interface process based on a communication standard of the Serial Peripheral Interface (SPI). However, these interface circuits may perform an interface process based on a communication standard of Inter-Integrated Circuit (I2C), a communication standard obtained by developing the SPI or I2C, or an interface process based on a communication standard obtained by improving or altering a part of the SPI or I2C standard.

The microcontroller 80 receives the first measurement data SD1 from the first sensor device 20X and the second measurement data SD2 from the second sensor device 20Y. The sensor module 10 includes a digital interface bus BS which electrically connects the first sensor device 20X and the second sensor device 20Y to the microcontroller 80. The digital interface bus BS is a bus conforming to a communication standard for the interface processes performed by the first interface circuit 70X and the second interface circuit 70Y. The digital interface bus BS includes data signal lines and clock signal lines. In the present embodiment, the digital interface bus BS includes a chip select signal line. The microcontroller 80 receives the first measurement data SD1 from the first sensor device 20X and the second measurement data SD2 from the second sensor device 20Y via the digital interface bus BS.

The first interface circuit 70X is electrically connected to the digital interface bus BS via the terminal TCS1, the terminal TCK1, the terminal TDI1, and the terminal TDO1. The second interface circuit 70Y is electrically connected to the digital interface bus BS via the terminal TCS2, the terminal TCK2, the terminal TDI2, and the terminal TDO2. The microcontroller 80 is electrically connected to the digital interface bus BS via a terminal TCS, a terminal TCK, a terminal TDI, and a terminal TDO. Here, the “electrical connection” indicates connection causing an electric signal to be transmitted, and also connection causing information using an electric signal to be transmitted.

The microcontroller 80 is a master controller of the first sensor device 20X and the second sensor device 20Y. The microcontroller 80 is an integrated circuit device, and may be implemented by a processor such as an MPU or a CPU. Alternatively, the microcontroller 80 may be implemented by an ASIC using automatic disposition wirings such as a gate array.

In the present embodiment, the first sensor device 20X has a first terminal used to input the synchronization signal SYC, and to input or output a communication signal. The first interface circuit 70X outputs the first measurement data SD1 to the microcontroller 80 based on the synchronization signal SYC input to the first terminal. The second sensor device 20Y includes a second terminal to which the synchronization signal SYC is input. The second interface circuit 70Y outputs the second measurement data SD2 to the microcontroller 80 based on the synchronization signal SYC input to the second terminal. The microcontroller 80 includes a third terminal used to input the synchronization signal SYC, and to output or input a communication signal. Therefore, the first sensor device 20X and the second sensor device 20Y may perform input of the synchronization signal SYC and input and output of a communication signal by using the first terminal and the second terminal. Consequently, each of the first sensor device 20X and the second sensor device 20Y can perform input of the synchronization signal SYC and input and output of a communication signal by using the common terminal, and thus a circuit of the sensor device can be simplified.

The communication signals are signals used to perform communication between the first sensor device 20X and the second sensor device 20Y, and the microcontroller 80. In the present embodiment, a chip select signal XCS, a clock signal SCLK, a data input signal SDI, and a data output signal SDO correspond to the communication signals. The chip select signal XCS is a signal that is output from the terminal TCS of the microcontroller 80 to the terminal TCS1 of the first sensor device 20X and the terminal TCS2 of the second sensor device 20Y. The clock signal SCLK is a signal that is output from the terminal TCK of the microcontroller 80 to the terminal TCK1 of the first sensor device 20X and the terminal TCK2 of the second sensor device 20Y. The data input signal SDI is a signal that is output from the terminal TDO of the microcontroller 80 to the terminal TDI1 of the first sensor device 20X and the terminal TDI2 of the second sensor device 20Y. The data output signal SDO is a signal that is output from the terminal TDO1 of the first sensor device 20X or the terminal TDO2 of the second sensor device 20Y to the terminal TDI of the microcontroller 80.

In the present embodiment, the first terminal of the first sensor device 20X is the terminal TDI1, the second terminal of the second sensor device 20Y is the terminal TDI2, and the third terminal of the microcontroller 80 is the terminal TDO. However, the first terminal, the second terminal, and the third terminal may be respectively the terminal TCS1, the terminal TCS2, and the terminal TCS, may be respectively the terminal TCK1, the terminal TCK2, and the terminal TCK, and may be respectively the terminal TDO1, the terminal TDO2, and the terminal TDO.

The selection circuit 11 selects whether or not the synchronization signal SYC is to be input to the first interface circuit 70X and the second interface circuit 70Y based on a signal from the microcontroller 80. In the present embodiment, the selection circuit 11 includes a buffer 12, a resistor 13, a pull-up resistor 14, and a pull-down resistor 15.

The buffer 12 is a three-state buffer having an input terminal, an output terminal, and a control terminal. The pull-down resistor 15 is electrically connected to the input terminal of the buffer 12, the pull-up resistor 14 is electrically connected to the control terminal of the buffer 12, and the resistor 13 is electrically connected to the output terminal of the buffer 12. An external synchronization signal EXSYC is input to the input terminal of the buffer 12, and a control signal CT output from a terminal TCT of the microcontroller 80 is input to the control terminal of the buffer 12. When the control signal CT is in a low level (L level), the buffer 12 is operated in a through mode in which the input terminal is electrically connected to the output terminal, and thus the external synchronization signal EXSYC input to the input terminal is output from the output terminal. The external synchronization signal EXSYC having passed through the buffer 12 is input to the first interface circuit 70X via the terminal TDI1, and is also input to the second interface circuit 70Y via the terminal TDI2, as the synchronization signal SYC. The synchronization signal SYC is input to the microcontroller 80 via the terminal TDO.

On the other hand, when the control signal CT has a high level (H level), the input terminal is electrically disconnected from the output terminal, and thus the buffer 12 is brought into a high impedance (Hi-Z) output state. In a case where the buffer 12 is in the Hi-Z output state, the microcontroller 80 can perform data communication with the first sensor device 20X and the second sensor device 20Y by making the chip select signal XCS active.

The terminal TDO of the microcontroller 80 is a terminal to which the synchronization signal SYC is input and from which the data input signal SDI is output, and can thus be used as an input terminal and an output terminal. Thus, the microcontroller 80 sets the terminal TDO as an output terminal before performing data communication with the first sensor device 20X or the second sensor device 20Y, and sets the terminal TDO as an input terminal before outputting the control signal CT having an L level from the terminal TCT. For example, the microcontroller 80 may set the terminal TDO as an input terminal or an output terminal by writing 0 or 1 into a register (not illustrated).

Here, the synchronization signal SYC is the external synchronization signal EXSYC or a signal based on the external synchronization signal EXSYC. As described above, in FIG. 1 , the synchronization signal SYC is the external synchronization signal EXSYC. The signal based on the external synchronization signal EXSYC is a signal generated by using the external synchronization signal EXSYC. For example, as illustrated in FIG. 3 which will be described later, the signal based on the external synchronization signal EXSYC is a signal generated, for example, by another circuit such as the microcontroller 80 sampling the external synchronization signal EXSYC with a clock signal. The external synchronization signal EXSYC is a signal which is input to the sensor module 10 from an external device such as a host device 210 in FIG. 7 which will be described later, and is a signal which becomes active every synchronization timing. For example, the external synchronization signal EXSYC is a signal which becomes active every predetermined period. An active state is a state in a high level (H level) in a case of a positive logic, and is a state in a low level (L level) in a case of a negative logic.

As mentioned above, in the sensor module 10 of the present embodiment, the first sensor device 20X outputs the first measurement data SD1 to the microcontroller 80 based on the synchronization signal SYC input to the terminal TDI1 which is the first terminal, and the second sensor device 20Y outputs the second measurement data SD2 to the microcontroller 80 based on the synchronization signal SYC input to the terminal TDI2 which is the second terminal. Therefore, each of the first sensor device 20X and the second sensor device 20Y can acquire measurement data at an appropriate timing by using the input synchronization signal SYC, and can output the measurement data to the microcontroller 80. Consequently, it is possible to achieve high accuracy of information measured by using the sensor module 10.

For example, in order to appropriately measure information such as posture information of a measurement target object, movement distance information, or inertial information based on measurement data from the first sensor device 20X and the second sensor device 20Y, it is desirable for pieces of measurement data to be synchronized with each other or for the time at which each piece of measurement data to be clear.

As regards this content, as a method of a first comparative example of the present embodiment, there may be a method in which each sensor device outputs measurement data acquired immediately before a measurement data output period, to the microcontroller 80. For example, it is assumed that the first sensor device 20X outputs the first measurement data SD1 in a first output period, and the second sensor device 20Y outputs the second measurement data SD2 in a second output period after the first output period. In this case, in the method of the first comparative example, the first sensor device 20X outputs the first measurement data SD1 acquired from the first measurement circuit 60X to the microcontroller 80 at a first timing immediately before the first output period. The second sensor device 20Y outputs the second measurement data SD2 acquired from the second measurement circuit 60Y to the microcontroller 80 at a second timing immediately before the second output period.

However, since the first timing and the second timing are timings which are temporally deviated relative to each other, an according to an acquisition timing for the first measurement data SD1 and an acquisition timing for the second measurement data SD2 are temporally deviated, and thus acquisition timings for measurement data are not synchronized with each other. For example, in a case where the first sensor device 20X and the second sensor device 20Y are respectively an X-axis angular velocity sensor device and a Y-axis angular velocity sensor device, an acquisition timing for X-axis angular velocity data and an acquisition timing for Y-axis angular velocity data are temporally deviated relative to each other. Therefore, in a case where posture information of a measurement target object such as a vehicle is measured based on such X-axis angular velocity data and Y-axis angular velocity data, accurate posture information cannot be measured.

As regards this fact, according to the present embodiment, the first sensor device 20X and the second sensor device 20Y can respectively output the first measurement data SD1 and the second measurement data SD2 acquired from the first measurement circuit 60X and the second measurement circuit 60Y, to the microcontroller 80 by using the common synchronization signal SYC. In other words, acquisition timings for the first measurement data SD1 and the second measurement data SD2 can be synchronized with each other. The angular velocity sensor devices can output, for example, X-axis angular velocity data and Y-axis angular velocity data which are acquired at a common synchronization timing, to the microcontroller 80. Therefore, in a case where posture information of a measurement target object is measured based on the X-axis angular velocity data and the Y-axis angular velocity data, it is possible to measure posture information with higher accuracy.

As a method of a second comparative example of the present embodiment, there may be a method in which, in a case where the microcontroller 80 issues a command with a plurality of sensor devices as common destinations, measurement data from each measurement circuit is acquired at a common fetch timing specified by issuing the command, and is output to the microcontroller 80. For example, each sensor device acquires measurement data from each measurement circuit and outputs the measurement data to the microcontroller 80 at a timing at which an issued command is determined as being a command with a plurality of sensor devices as common destinations as a result of analysis of the command.

However, issuing of a command in the microcontroller 80 is not performed at each constant time, and there is a temporal fluctuation in an issue timing. Thus, a fluctuation occurs in an acquisition timing for measurement data, and information such as posture information of a measurement target object acquired by using the sensor module 10 is not accurate and not appropriate due to the fluctuation. The microcontroller 80 performs not only a process of issuing a command to the sensor device but also various processes. Thus, in a case where there is an interruption request having high priority, the interruption process is preferentially performed, and thus the process of issuing a command to the sensor device is delayed. Therefore, due to other interruption requests, a temporal fluctuation occurs in a timing of issuing a command to the sensor device, and thus a temporal fluctuation occurs in an acquisition timing for measurement data.

As regards this fact, according to the present embodiment, each sensor device can acquire measurement data from the measurement circuit so as to output the measurement data by using the synchronization signal SYC regardless of a process performed by the microcontroller 80. For example, even in a case where the microcontroller 80 performs a process having a high interruption priority, measurement data can be acquired at a synchronization timing of the synchronization signal SYC regardless thereof. Therefore, it is possible to prevent the problem that a temporal fluctuation occurs at an acquisition timing for measurement data.

For example, in the present embodiment, the first interface circuit 70X outputs the first measurement data SD1 fetched from the first measurement circuit 60X at a synchronization timing of the synchronization signal SYC, to the microcontroller 80. The second interface circuit 70Y outputs the second measurement data SD2 received from the second measurement circuit 60Y at the synchronization timing of the synchronization signal SYC, to the microcontroller 80.

In the above-described way, the first interface circuit 70X can hold the first measurement data SD1 fetched at the synchronization timing in a register or the like. In a case where the microcontroller 80 issues a read command for the measurement data, the first interface circuit 70X can output the held first measurement data SD1 to the microcontroller 80. Therefore, the first interface circuit 70X can acquire the first measurement data SD1 from the first measurement circuit 60X at the synchronization timing of the synchronization signal SYC without depending on a command issue timing of the microcontroller 80, and can output the first measurement data SD1 to the microcontroller 80 when a command is issued. Similarly, the second interface circuit 70Y can hold the second measurement data SD2 fetched at the synchronization timing in a register or the like. In a case where the microcontroller 80 issues a read command for the measurement data, the second interface circuit 70Y can output the held second measurement data SD2 to the microcontroller 80. Therefore, the second interface circuit 70Y can acquire the second measurement data SD2 from the second measurement circuit 60Y at the synchronization timing of the synchronization signal SYC without depending on a command issue timing of the microcontroller 80, and can output the second measurement data SD2 to the microcontroller 80 when a command is issued. Therefore, it is possible to prevent the problem of a temporal fluctuation in an acquisition timing for measurement data, which is problematic in the method of the second comparative example.

FIG. 2 is a diagram illustrating a configuration example of the microcontroller 80. The microcontroller 80 includes a digital interface circuit 82, a processing circuit 90, a signal processing circuit 92, an interruption controller 94, and a host interface circuit 96. The digital interface circuit 82 is a circuit which performs an interface process with the sensor device. In other words, the digital interface circuit 82 performs an interface process as a master of the first interface circuit 70X and the second interface circuit 70Y. The digital interface circuit 82 is connected to the digital interface bus BS via the terminal TCS, the terminal TCK, the terminal TDO, and the terminal TDI. In the present embodiment, the digital interface circuit 82 performs an interface process based on a communication standard of the SPI in the same manner as the first interface circuit 70X and the second interface circuit 70Y. However, the digital interface circuit 82 may perform an interface process based on a communication standard of the I2C, or a communication standard obtained by developing the SPI or the I2C, or an interface process based on a communication standard obtained by improving or altering a part of the SPI or I2C standard.

The processing circuit 90 is a circuit corresponding to a core CPU of the microcontroller 80, and performs various calculation processes or control processes. The processing circuit 90 includes a register portion 91 having various registers. The signal processing circuit 92 is a circuit which performs a digital signal process such as a filtering process or a correction process, and may be implemented by a DSP or the like. Specifically, the signal processing circuit 92 performs a process of computing a moving average of the latest J pieces of measurement data with respect to measurement data and then down-sampling the measurement data at a rate of 1/K (where J and K are integers of 2 or greater). The signal processing circuit 92 performs a correction process such as temperature correction on the measurement data having undergone a filtering process. The processing circuit 90 performs a process of storing the measurement data having undergone the correction process in the register portion 91. The processing circuit 90 generates a signal DRDY which is a measurement data preparation completion signal, and outputs a signal DRDY to a host device 210 in FIG. 7 which will be described later via a terminal TR. The signal DRDY is a signal indicating that a digital signal process in the signal processing circuit 92 is completed.

The register portion 91 has a plurality of registers which can be accessed from the outside. For example, the host device 210 may access a data register of the register portion 91 via the host interface circuit 96, and read the measurement data. The processing circuit 90 performs a process of counting the number of the measurement data being updated in the data register. The counted update number is written into an update number register of the register portion 91. Consequently, the host device 210 can specify which number of data is read as the measurement data from the microcontroller 80.

The processing circuit 90 writes 0 or 1 into a predetermined bit of a control register of the register portion 91, and thus outputs the control signal CT having an L level or an H level from the terminal TCT. As illustrated in FIG. 1 , since the terminal TCT is electrically connected to the pull-up resistor 14, the processing circuit 90 may bring the terminal TCT into a Hi-Z state such that the control signal CT has an H level.

The processing circuit 90 writes 0 or 1 into a predetermined bit of the control register of the register portion 91, so as to set the terminal TDO as an input terminal or an output terminal. Specifically, the processing circuit 90 sets the terminal TDO as an output terminal before performing data communication with the first sensor device 20X or the second sensor device 20Y, and sets the terminal TDO as an input terminal before outputting the control signal CT having an L level from the terminal TCT.

The interruption controller 94 receives various interruption requests. The interruption controller 94 outputs signals indicating an interruption request, an interruption level, and a vector number to the processing circuit 90 depending on a priority order and the interruption level. As one of interruption request signals, the external synchronization signal EXSYC is input to the interruption controller 94 via the terminal TDO. In a case where an interruption request using the external synchronization signal EXSYC is received, the processing circuit 90 performs a corresponding interruption process. Examples of interruption requests include an interruption request using an SPI or a Universal Asynchronous Receiver Transmitter (UART) of the host interface circuit 96, interruption requests using various timers, and an interruption request using an I2C.

The host interface circuit 96 is a circuit which performs a digital interface process with the host device 210 via one or a plurality of terminals TH. For example, the host interface circuit 96 performs serial data communication such as an SPI or UART as the host interface process.

FIG. 3 illustrates another configuration example of the microcontroller 80. In FIG. 3 , a synchronization signal output circuit 88 is additionally provided in the microcontroller 80. The synchronization signal output circuit 88 receives the external synchronization signal EXSYC via a terminal TE, and outputs an internal synchronization signal INSYC which is generated based on the external synchronization signal EXSYC. Specifically, the synchronization signal output circuit 88 samples the external synchronization signal EXSYC based on an internal clock signal of the microcontroller 80, and outputs a resynchronized signal of the external synchronization signal EXSYC as the internal synchronization signal INSYC. The internal synchronization signal INSYC is output to the input terminal of the buffer 12 via a terminal TSQ. The internal synchronization signal INSYC is output as the synchronization signal SYC from the output terminal of the buffer 12 when the control signal CT has an L level. The synchronization signal SYC is input to the first sensor device 20X and the second sensor device 20Y via the terminal TDI1 and the terminal TDI2.

In a case of FIGS. 1 and 2 , the external synchronization signal EXSYC is input to the first sensor device 20X and the second sensor device 20Y as the synchronization signal SYC. In contrast, in FIG. 3 , the internal synchronization signal INSYC which is a resynchronized signal based on the external synchronization signal EXSYC is input as the synchronization signal SYC to the first sensor device 20X and the second sensor device 20Y. In a case where the external synchronization signal EXSYC contains a lot of noise components, preferably, the external synchronization signal EXSYC is sampled with the internal clock signal, and is supplied to the first sensor device 20X and the second sensor device 20Y as the synchronization signal SYC.

FIG. 4 is a signal waveform diagram for explaining an operation of the sensor module 10. As illustrated in FIG. 4 , the external synchronization signal EXSYC becomes active every synchronization timing. In other words, the external synchronization signal EXSYC becomes active at a predetermined time interval. The external synchronization signal EXSYC is input to the terminal TDI1 and the terminal TDI2 of the first sensor device 20X and the second sensor device 20Y as the synchronization signal SYC. Then, at a synchronization timing t1 at which the synchronization signal SYC which is the external synchronization signal EXSYC becomes active (H level), as indicated by E2 in FIG. 4 , first measurement data SSD1 from the first measurement circuit 60X and second measurement data SSD2 from the second measurement circuit 60Y are fetched. Specifically, the first measurement data SSD1 and the second measurement data SSD2 are fetched to a register 67 in FIG. 5 which will be described later. FIG. 4 also illustrates n-th measurement data SSDn from an n-th measurement circuit.

In the present embodiment, the first sensor device 20X and the second sensor device 20Y operate based on separate clock signals. For example, each sensor device operates based on a clock signal from an oscillation circuit built into the sensor device or a clock signal generated by using a resonator such as a quartz crystal resonator of the sensor device. Thus, as indicated by E2 in FIG. 4 , pieces of measurement data are output in an asynchronization manner from the measurement circuits of the respective sensor devices. In the present embodiment, the measurement data is latched and fetched with the synchronization signal SYC having an identical synchronization timing. As indicated by E3, the fetched measurement data is output to the microcontroller 80 from the first sensor device 20X and the second sensor device 20Y as the first measurement data SD1 and the second measurement data SD2. As will be described later, actually, the microcontroller 80 issues a read command, and the first measurement data SD1 and the second measurement data SD2 are output based on the read command.

On the other hand, in the present embodiment, the external synchronization signal EXSYC is also input to the microcontroller 80 via the terminal TDO. In a case where the external synchronization signal EXSYC becomes active at E1 in FIG. 4 , the interruption controller 94 receives this state, and, as indicated by E4, an interruption process based on a signal SYCINT is started. The measurement data output at E3 is fetched to the microcontroller 80 via the digital interface circuit 82 as measurement data SDAT as indicated by E5. Next, as indicated by E6, a digital signal process is started by the signal processing circuit 92. For example, a filtering process such as a moving average process is performed, and then a correction process such as temperature correction is performed such that measurement data SDATC having undergone the correction process is generated as indicated by E7. Then, the digital signal process is completed, and the signal DRDY indicating data preparation completion is output to the host device 210 via the terminal TR. The host device 210 accesses the register portion 91 via the host interface circuit 96, and thus measurement data SDATQ is output to the host device 210 as indicated by E9.

Similarly, in a case where the external synchronization signal EXSYC becomes active at the next synchronization timing t2 as indicated by E11, measurement data from the measurement circuit of each sensor device is fetched as indicated by E12, and the measurement data is output from each sensor device as indicated by E13. As indicated by E14, E15, E16, and E17, the microcontroller 80 performs an interruption process or a digital signal process, and, as indicated by E18 and E19, the signal DRDY is output such that the measurement data SDATQ is output. In a case where the external synchronization signal EXSYC becomes active at the next synchronization timing t3 as indicated by E21, fetch and output of measurement data are performed in each sensor device as indicated by E22 and E23, and each process is performed in the microcontroller 80 as indicated by E24. The same processes are performed as indicated by E25, E26, E27, and E28 in FIG. 4 .

As described above, in the present embodiment, as indicated by E2, E12, E22, and E26, each of a plurality of sensor devices fetches measurement data from the measurement circuit at an identical synchronization timing based on the external synchronization signal EXSYC. Therefore, it is guaranteed that measurement data from a plurality of sensor devices is measurement data acquired at an identical synchronization timing. It is guaranteed that, for example, in the three-axis angular velocity sensor devices, X-axis angular velocity data, Y-axis angular velocity data, and Z-axis angular velocity data are measurement data acquired at an identical synchronization timing. Therefore, in a case where the host device 210 obtains posture information of a measurement target object by using the X-axis angular velocity data, the Y-axis angular velocity data, and the Z-axis angular velocity data, it is possible to measure more appropriate and accurate posture information or the like.

FIG. 5 illustrates a configuration example of a sensor device 20. The sensor device 20 (20X or 20Y) includes the sensor element 50 (50X or 50Y), a measurement circuit 60 (60X or 60Y), a processing circuit 66, and an interface circuit 70 (70X or 70Y). The measurement circuit 60 includes an analog circuit 62 having an amplification circuit 63 which amplifies a signal from the sensor element 50, and an A/D conversion circuit 64 which converts an analog signal from the analog circuit 62 into digital data. The processing circuit 66 includes the register 67. The interface circuit 70 includes a parallel/serial conversion circuit 72, a serial/parallel conversion circuit 74, and a control circuit 76 which performs an interface control process based on the chip select signal XCS and the clock signal SCLX. Configurations of the digital interface circuit 82 and the host interface circuit 96 of the microcontroller 80 are the same as the configuration of the interface circuit 70.

The A/D conversion circuit 64 samples an analog measurement signal from the analog circuit 62 so as to perform A/D conversion based on a clock signal ADCK with a frequency f1. Measurement data ADQ is output at an output sampling rate corresponding to the frequency f1. Then, the register 67 fetches the measurement data ADQ from the A/D conversion circuit 64 thereinto based on the synchronization signal SYC with a frequency f2 when the chip select signal XCS is inactive. Specifically, as indicated by E2, E12, E22, and E26 in FIG. 4 , the register 67 latches and holds the measurement data ADQ at a synchronization timing of the synchronization signal SYC. In a case where a resolution in A/D conversion of the A/D conversion circuit 64 is k bits, the measurement data ADQ is, for example, k-bit parallel data. The measurement data ADQ held in the register 67 is converted into serial data by the parallel/serial conversion circuit 72 of the interface circuit 70, and the serial data is output to the microcontroller 80 as the data output signal SDO. Serial data of the data input signal SDI from the microcontroller 80 is converted into parallel data by the serial/parallel conversion circuit 74.

Here, the frequency f2 of the synchronization signal SYC is equal to or less than, for example, 1 KHz, and is about 100 Hz, for example, and is thus sufficiently lower than the frequency f1 of the clock signal ADCK of the A/D conversion circuit 64. Therefore, among pieces of measurement data which are sequentially output in a time series from the A/D conversion circuit 64 at the output sampling rate of the frequency f1, measurement data at an appropriate synchronization timing based on the synchronization signal SYC can be latched and held in the register 67. Consequently, even in a case where a temporal fluctuation occurs in a command issue timing of the microcontroller 80 due to other interruption processes, measurement data latched in the register 67 at an appropriate synchronization timing can be output as the data output signal SDO when a command is issued.

FIG. 6 is a flowchart illustrating an operation of the microcontroller 80. First, the microcontroller 80 sets the terminal TDO as an input terminal for the synchronization signal SYC (step S11), and sets the buffer 12 in a through mode (step S12).

Next, the microcontroller 80 determines whether or not an interruption request is made (step S13). Specifically, the microcontroller 80 determines whether or not an interruption request signal is input to the interruption controller 94.

In a case where the interruption request is made (Y in step S13), an interruption cause thereof is determined (step S14). In a case where there is another interruption request having a higher priority order (Y in step S15), the microcontroller 80 performs a process corresponding to another interruption request (step S16).

In a case where there is no other interruption request having a higher priority order (N in step S15), and the interruption request is not an interruption request based on the external synchronization signal EXSYC (N in step S17), the microcontroller 80 performs a process corresponding to the interruption request (step S18), and performs the processes in step S11 and the subsequent steps.

In a case where there is no other interruption request having a higher priority order (N in step S15), and the interruption request is an interruption request based on the external synchronization signal EXSYC (Y in step S17), the microcontroller 80 performs processes from step S19 to step S25 as interruption processes based on the external synchronization signal EXSYC.

Specifically, first, the microcontroller 80 sets the buffer 12 in a Hi-Z output state (step S19), and sets the terminal TDO as an output terminal for the data input signal SDI (step S20).

Next, the microcontroller 80 performs a process of issuing a command for reading measurement data from the second marker 20 (step S21).

An interruption request having a higher priority order than an interruption request based on the external synchronization signal EXSYC includes, for example, an interruption request based on an SPI or a UART of the host interface circuit 96. For example, the interruption request is an interruption request for the host device 210 accessing the register portion 91. In a case where there is an interruption request having a higher priority order, the microcontroller 80 delays execution of the interruption process based on the external synchronization signal EXSYC. The process corresponding to the interruption request having a higher priority order is finished, and then the interruption process based on the external synchronization signal EXSYC is performed. A temporal fluctuation occurs in a timing of issuing a measurement data read command due to the delay time.

The microcontroller 80 issues the read command, and then performs a process of reading measurement data from the sensor device 20 (step S22). Consequently, as indicated by E3 in FIG. 4 , the measurement data from the sensor device 20 is read. The read measurement data is data fetched to the register 67 from the measurement circuit 60 at a synchronization timing of the synchronization signal SYC as indicated by E2. Therefore, even in a case where a temporal fluctuation occurs in the read command issue timing in step S21, a temporal fluctuation does not occur in an acquisition timing for measurement data from the sensor device 20.

Next, the microcontroller 80 performs a digital signal process on the measurement data read from the sensor device 20 (step S23). Specifically, a filtering process or a temperature correction process is performed. It is determined whether or not the digital signal process is finished (step S24), and, in a case where the digital signal process is finished (Y in step S24), the signal DRDY indicating completion of preparation of the measurement data having undergone the digital signal process is output to the host device 210 (step S25), and the processes in step S11 and the subsequent steps are performed again.

As mentioned above, in the present embodiment, as illustrated in FIGS. 2 and 3 , the microcontroller 80 includes the terminal TDO to which the external synchronization signal EXSYC is input. Therefore, the external synchronization signal EXSYC can be input not only to the sensor device 20 but also to the microcontroller 80. Consequently, the microcontroller 80 can perform a process of issuing a command to the sensor device 20 or perform a process of reading measurement data from the sensor device 20 by using the external synchronization signal EXSYC as a trigger.

In the present embodiment, the microcontroller 80 includes the interruption controller 94, and the external synchronization signal EXSYC is input to the interruption controller 94. In the above-described way, the microcontroller 80 can perform an interruption process corresponding to the external synchronization signal EXSYC with the external synchronization signal EXSYC as an interruption cause. In other words, the microcontroller 80 can perform a process of issuing a command to the sensor device 20 or perform a process of reading measurement data from the sensor device 20 by using the external synchronization signal EXSYC as an interruption request signal.

The microcontroller 80 includes the processing circuit 90, and the processing circuit 90 performs a command issuing process for acquiring the first measurement data SD1 from the first sensor device 20X and the second measurement data SD2 from the second sensor device 20Y with the external synchronization signal EXSYC as an interruption cause. In other words, the processing circuit 90 performs a process of issuing a command for reading the first measurement data SD1 and the second measurement data SD2. In the above-described way, the processing circuit 90 determines whether or not there is another interruption request having a higher priority order, and performs a command issuing process which is an interruption process based on the external synchronization signal EXSYC in a case where such an interruption request is not present. On the other hand, in a case where there is another interruption request having a higher priority order, a process corresponding to the interruption request may be performed, and then a process of issuing a command for reading the first measurement data SD1 and the second measurement data SD2 may be performed. Since an interruption request having a higher priority order is performed as mentioned above, even in a case where a temporal fluctuation occurs in a command issue timing, measurement data is fetched at a synchronization timing, and thus a problem caused by the temporal fluctuation does not occur.

In the present embodiment, the microcontroller 80 includes the signal processing circuit 92 which performs a digital signal process on the first measurement data SD1 from the first sensor device 20X and the second measurement data SD2 from the second sensor device 20Y. The signal processing circuit 92 performs a digital signal process every synchronization timing of the external synchronization signal EXSYC. The signal processing circuit 92 performs a digital signal process such as a filtering process or a correction process. For example, in a case where the external synchronization signal EXSYC becomes active as indicated by E1 in FIG. 4 , the signal processing circuit 92 performs a digital signal process as indicated by E6. Next, in a case where the external synchronization signal EXSYC becomes active as indicated by E11, the signal processing circuit 92 performs a digital signal process as indicated by E16. In other words, the signal processing circuit 92 performs a digital signal process every synchronization timing of the external synchronization signal EXSYC as indicated by E1 and E11. In the above-described way, the signal processing circuit 92 can perform a digital signal process on measurement data acquired from the measurement circuit 60 at the synchronization timing of E1, at the timing of E6 corresponding to the synchronization timing of E1. Similarly, the signal processing circuit 92 can perform a digital signal process on measurement data acquired from the measurement circuit 60 at the synchronization timing of E11, at the timing of E16 corresponding to the synchronization timing of E11. Therefore, the signal processing circuit 92 can perform a digital signal process on measurement data acquired at an appropriate synchronization timing, at a timing corresponding to the synchronization timing.

In a case where a digital signal process is completed, the microcontroller 80 outputs the signal DRDY indicating completion of the digital signal process to the outside. For example, at the synchronization timing of E1 in FIG. 4 , a digital signal process is performed, and the digital signal process is completed, as indicated by E6, and, in a case where measurement data SDATC having undergone the digital signal process is generated as indicated by E7, the signal DRDY is output to the outside as indicated by E8. Similarly, at the synchronization timing of E11, a digital signal process is performed, and the digital signal process is completed, as indicated by E16, and, in a case where measurement data SDATC having undergone the digital signal process is generated as indicated by E17, the signal DRDY is output to the outside as indicated by E18. In the above-described way, in a case where a digital signal process is performed, and the digital signal process is completed, in each synchronization period defined by the synchronization timings of E1 and E11, the microcontroller 80 can notify the external host device 210 of the completion by using the signal DRDY.

In the present embodiment, the microcontroller 80 includes the host interface circuit 96, and outputs the first measurement data and the second measurement data having undergone a digital signal process to the outside via the host interface circuit 96. For example, in the synchronization period based on the synchronization timing of E1, in a case where measurement data SDATC having undergone the digital signal process is generated as indicated by E7, the measurement data is output to the host device 210 via the host interface circuit 96 as measurement data SDATQ as indicated by E9. In the synchronization period based on the synchronization timing of E11, in a case where measurement data SDATC having undergone the digital signal process is generated as indicated by E17, the measurement data is output to the host device 210 via the host interface circuit 96 as measurement data SDATQ as indicated by E19. The measurement data SDATQ is measurement data generated by performing digital signal processes on the first measurement data SD1 from the first sensor device 20X and the second measurement data SD2 from the second sensor device 20Y. In the above-described way, in a case where a digital signal process is completed in each synchronization period, and measurement data having undergone the digital signal process can be acquired, the microcontroller 80 can output the measurement data to the host device 210 via the host interface circuit 96.

In the present embodiment, in the first sensor device 20X, the terminal TDI1 used for data communication with the microcontroller 80 is also used as a terminal to which the synchronization signal SYC is input. Similarly, in the second sensor device 20Y, the terminal TDI2 used for data communication with the microcontroller 80 is also used as a terminal to which the synchronization signal SYC is input. In the microcontroller 80, the terminal TDO used for data communication with the first sensor device 20X and the second sensor device 20Y is also used as a terminal to which the synchronization signal SYC is input. Therefore, according to the present embodiment, it is possible to reduce the number of terminals of the first sensor device 20X, the second sensor device 20Y, and the microcontroller 80, and thus there is an advantage in miniaturization of the sensor module 10.

FIG. 7 illustrates a specific configuration example of the sensor module 10 in a case where the sensor device 20 is an angular velocity sensor device and an acceleration sensor device. The sensor module 10 in FIG. 7 includes an X-axis angular velocity sensor device 30X, a Y-axis angular velocity sensor device 30Y, a Z-axis angular velocity sensor device 30Z, an acceleration sensor device 40, the microcontroller 80, the selection circuit 11, a first digital interface bus BS1, and a second digital interface bus BS2. A six-axis inertial measurement unit (IMU) may be implemented by the sensor module 10 having the configuration illustrated in FIG. 7 . It is possible to detect an attitude or a behavior which is moment of inertia of a motion object such as an automobile or a robot as a vehicle by using the inertial measurement unit.

The X-axis angular velocity sensor device 30X measures an angular velocity about an X axis, and outputs digital X-axis angular velocity data. The X-axis angular velocity data is digital data indicating an angular velocity about the X axis. The X-axis angular velocity sensor device 30X includes a sensor element measuring an angular velocity about the X axis. The sensor element is, for example, a gyro sensor element configured with a piezoelectric vibrator such as a quartz crystal resonator. However, the sensor element is not limited thereto, and may be a Si-MEMS gyro sensor element of an electrostatic capacitance measurement type, formed from a silicon substrate. For example, the sensor element may be obtained by multiply connecting a plurality of Si-MEMS gyro sensor elements to each other. The X-axis angular velocity sensor device 30X includes an analog circuit having an amplification circuit which amplifies a measurement signal from the sensor element or a synchronous detecting circuit which performs synchronous detection on the measurement signal. The X-axis angular velocity sensor device 30X includes an A/D conversion circuit which converts an analog signal from the analog circuit into digital data. Output data from the A/D conversion circuit, or data obtained by performing a correction process such as temperature correction, offset correction, or sensitivity correction on the output data is X-axis angular velocity data.

The Y-axis angular velocity sensor device 30Y measures an angular velocity about a Y axis, and outputs digital Y-axis angular velocity data. The Y-axis angular velocity data is digital data indicating an angular velocity about the Y axis. The Y-axis angular velocity sensor device 30Y includes a sensor element measuring an angular velocity about the Y axis. As the sensor element, various types of sensor elements may be used as described above. The Y-axis angular velocity sensor device 30Y includes an analog circuit having an amplification circuit which amplifies a measurement signal from the sensor element or a synchronous detecting circuit, and an A/D conversion circuit which converts an analog signal from the analog circuit into digital data. Output data from the A/D conversion circuit, or data obtained by performing a correction process on the output data is Y-axis angular velocity data.

The Z-axis angular velocity sensor device 30Z measures an angular velocity about a Z axis, and outputs digital Z-axis angular velocity data. The Z-axis angular velocity data is digital data indicating an angular velocity about the Z axis. The Z-axis angular velocity sensor device 30Z includes a sensor element measuring an angular velocity about the Z axis. As the sensor element, various types of sensor elements may be used as described above. The Z-axis angular velocity sensor device 30Z includes an analog circuit having an amplification circuit which amplifies a measurement signal from the sensor element or a synchronous detecting circuit, and an A/D conversion circuit which converts an analog signal from the analog circuit into digital data. Output data from the A/D conversion circuit, or data obtained by performing a correction process on the output data is Z-axis angular velocity data.

The acceleration sensor device 40 measures an acceleration in the X axis direction, an acceleration in the Y axis direction, and an acceleration in the Z axis direction, and outputs digital X-axis acceleration data, Y-axis acceleration data, and Z-axis acceleration data. The X-axis acceleration data is digital data indicating an acceleration in the X axis direction. Similarly, the Y-axis acceleration data and the Z-axis acceleration data are digital data respectively indicating an acceleration in the Y axis direction and an acceleration in the Z axis direction. The acceleration sensor device 40 is, for example, a Si-MEMS sensor device of the electrostatic capacitance type which can measure accelerations in the X axis direction, the Y axis direction, and the Z axis direction with a single device. However, the present embodiment is not limited thereto, and the acceleration sensor device 40 may be a frequency change type quartz crystal acceleration sensor, a piezoelectric resistance type acceleration sensor, or a heat sensing type acceleration sensor.

The acceleration sensor device 40 includes a sensor element for measuring an X-axis acceleration, a sensor element for measuring a Y-axis acceleration, and a sensor element for measuring a Z-axis acceleration. As a sensor element for measuring each axis acceleration, a plurality of sensor elements may be provided. The acceleration sensor device 40 includes an analog circuit having an amplification circuit which amplifies a measurement signal from the sensor element for measuring each axis acceleration, and an A/D conversion circuit which converts an analog signal from the analog circuit into digital data. The A/D conversion circuit converts, for example, an analog signal of the X-axis acceleration, an analog signal of the Y-axis acceleration, and an analog signal of the Z-axis acceleration, into digital data in a time division manner. Output data from the A/D conversion circuit, or data obtained by performing a correction process such temperature correction on the output data is X-axis acceleration data, Y-axis acceleration data, and Z-axis acceleration data.

The X axis, the Y axis, and the Z axis here are an X axis, a Y axis, and a Z axis as measurement axes of the sensor module 10. The Z axis is, for example, an axis in a direction orthogonal to an attachment surface of a measurement target object to which the sensor module 10 is attached. The attachment surface may be amounting surface on which the sensor module 10 is mounted. A thickness direction of the sensor module 10 in FIG. 15 which will be described later may be a direction of the Z axis. The X axis and the Y axis are orthogonal to each other, and are axes orthogonal to the Z axis. Directions of the X axis and the Y axis may be any directions, but, in FIG. 15 , an axis parallel to a first side of a square shape of the sensor module 10 in a plan view may be set as the X axis, and an axis parallel to a second side of the square shape orthogonal to the first side may be set as the Y axis.

The microcontroller 80 includes a first digital interface circuit 83 and a second digital interface circuit 84. The first digital interface circuit 83 and the second digital interface circuit 84 are circuits performing a digital interface process, and perform, for example, transmission or reception of serial data. The first digital interface circuit 83 and the second digital interface circuit 84 perform an interface process based on an SPI or I2C communication standard. However, the first digital interface circuit 83 and the second digital interface circuit 84 may perform an interface process based on a communication standard of the I2c, an interface process based on a communication standard obtained by developing the SPI or the I2C, or an interface process based on a communication standard obtained by improving or altering a part of the SPI or I2C standard.

The first digital interface bus BS1 is a bus which electrically connects the X-axis angular velocity sensor device 30X, the Y-axis angular velocity sensor device 30Y, and the Z-axis angular velocity sensor device 30Z to the first digital interface circuit 83 of the microcontroller 80. The X-axis angular velocity data from the X-axis angular velocity sensor device 30X, the Y-axis angular velocity data from the Y-axis angular velocity sensor device 30Y, and the Z-axis angular velocity data from the Z-axis angular velocity sensor device 30Z are input to the microcontroller 80 via the first digital interface bus BS1.

The second digital interface bus BS2 is a bus which electrically connects the acceleration sensor device 40 to the second digital interface circuit 84 of the microcontroller 80. The X-axis acceleration data, the Y-axis acceleration data, and the Z-axis acceleration data from the acceleration sensor device 40 are input to the microcontroller 80 via the second digital interface bus BS2.

The first digital interface bus BS1 is a bus conforming to the communication standard for the interface process performed by the first digital interface circuit 83. The second digital interface bus BS2 is a bus conforming to the communication standard for the interface process performed by the second digital interface circuit 84. Each of the first digital interface bus BS1 and the second digital interface bus BS2 includes data signal lines and clock signal lines. A chip select signal line may be included. The first digital interface bus BS1 and the second digital interface bus BS2 are wired on a circuit substrate 100 of the sensor module 10 illustrated in FIG. 15 .

The microcontroller 80 includes the host interface circuit 96 which is a third digital interface circuit connected to the host device 210. The host interface circuit 96 is a circuit performing a digital interface process, and performs, for example, transmission or reception of serial data. The host interface circuit 96 may be implemented by using, for example, an SPI or a UART.

Also in the configuration illustrated in FIG. 7 , the external synchronization signal EXSYC as the synchronization signal SYC is input to the X-axis angular velocity sensor device 30X, the Y-axis angular velocity sensor device 30Y, the Z-axis angular velocity sensor device 30Z, and the acceleration sensor device 40. In other words, each sensor device is provided with a terminal for data communication with the microcontroller 80 as described in FIG. 1 , and the external synchronization signal EXSYC is input as the synchronization signal SYC via the terminal. As mentioned above, in FIG. 7 , a data communication signal line included in each of the first digital interface bus BS1 and the second digital interface bus BS2 is also used as a signal line for the synchronization signal SYC.

FIG. 8 illustrates another configuration example of the sensor module 10. The sensor module 10 in FIG. 8 further includes a second acceleration sensor device 40B in addition to a first acceleration sensor device 40A which is the acceleration sensor device 40 in FIG. 7 . The first acceleration sensor device 40A and the second acceleration sensor device 40B are electrically connected to the second digital interface circuit 84 of the microcontroller 80 via the second digital interface bus BS2. The external synchronization signal EXSYC as the synchronization signal SYC is also input to the first acceleration sensor device 40A and the second acceleration sensor device 40B.

According to the configuration in which a plurality of acceleration sensor devices are provided as in FIG. 8 , an average value or the like which is a statistical value of acceleration data from the plurality of acceleration sensor devices is calculated in the microcontroller 80, and thus high accuracy of acceleration data can be realized. For example, the microcontroller 80 obtains an average value of X-axis acceleration data from the first acceleration sensor device 40A and X-axis acceleration data from the second acceleration sensor device 40B, and outputs the obtained average value to a host device 210 or the like as final X-axis acceleration data. The microcontroller 80 obtains an average value of Y-axis acceleration data from the first acceleration sensor device 40A and Y-axis acceleration data from the second acceleration sensor device 40B, and outputs the obtained average value as final Y-axis acceleration data. The microcontroller 80 obtains an average value of Z-axis acceleration data from the first acceleration sensor device 40A and Z-axis acceleration data from the second acceleration sensor device 40B, and outputs the obtained average value as final Z-axis acceleration data.

In the present embodiment, in a case where a plurality of acceleration sensor devices are provided as mentioned above, the common synchronization signal SYC is input to the plurality of acceleration sensor devices. For example, in the method of the first comparative example, fetch timings for a plurality of pieces of acceleration data used to calculate an average value of the acceleration data are different from each other, and thus there is a problem in that the microcontroller 80 cannot obtain an appropriate average value. As regards this fact, according to the present embodiment, in a case where acceleration data in an identical coordinate axis is measured by using a plurality of acceleration sensor devices, and an average value thereof is obtained, the microcontroller 80 can obtain an average value by using a plurality of pieces of acceleration data fetched at an identical synchronization timing based on the synchronization signal SYC, and can thus obtain an appropriate average value.

In the present embodiment, a plurality of angular velocity sensor devices may be provided as each of X-axis, Y-axis, and Z-axis angular velocity sensor devices. Specifically, the sensor module 10 may include at least one of a second X-axis angular velocity sensor device, a second Y-axis angular velocity sensor device, and a second Z-axis angular velocity sensor device. In this case, at least one sensor device is electrically connected to the first digital interface circuit 83 of the microcontroller 80 via the first digital interface bus BS1. The external synchronization signal EXSYC as the synchronization signal SYC is also input to at least one sensor device.

For example, it is assumed that the second Z-axis angular velocity sensor device 30 is provided as at least one sensor device. In this case, the microcontroller 80 obtains an average value of Z-axis angular velocity data from the Z-axis angular velocity sensor device 30Z and Z-axis angular velocity data from the second Z-axis angular velocity sensor device 30, and outputs the obtained average value to the host device 210 as final Z-axis angular velocity data. Consequently, it is possible to achieve high accuracy of Z-axis angular velocity data. For X-axis angular velocity data and Y-axis angular velocity data, a plurality of corresponding angular velocity devices are provided, an average value is obtained, and thus it is possible to achieve high accuracy of angular velocity data. In a case where angular velocity data for an identical coordinate axis is measured by using the plurality of angular velocity sensor devices, and an average value thereof is obtained, an average value can be obtained by using a plurality of pieces of angular velocity data fetched at an identical synchronization timing based on the synchronization signal SYC, and thus an appropriate average value can be obtained.

In a vehicle such as an automobile, it is important to measure yawing rotational motion corresponding to rotational motion about the Z axis. Therefore, it is necessary to achieve high accuracy of a Z-axis angular velocity required to measure a yaw angular velocity or a yaw angle, and, in this sense, preferably, the second Z-axis angular velocity sensor device 30 is provided, and an average value of pieces of Z-axis angular velocity data from a plurality of angular velocity sensor devices is obtained.

FIG. 9 is a diagram illustrating a signal waveform example in the first digital interface bus BS1. The first digital interface bus BS1 includes signal lines for a chip select signal XCS, a clock signal SCLK, a data input signal SDI, and a data output signal SDO. First, the chip select signal XCS in a negative logic has an L level. Consequently, all of the X-axis angular velocity sensor device 30X, the Y-axis angular velocity sensor device 30Y, and the Z-axis angular velocity sensor device 30Z which are connected in common to the signal line for the chip select signal XCS are selected as chips. R/W of a first 1 bit of the data input signal SDI is a bit giving an instruction for read/write. In a case where R/W is 1, an instruction for read is given, and in a case where R/W is 0, an instruction for write is given. A[1:0] of 2 bits after R/W designates an address. In a case where a common address is designated, A[1:0]=00 is set. In a case where individual addresses of the X-axis angular velocity sensor device 30X, the Y-axis angular velocity sensor device 30Y, and the Z-axis angular velocity sensor device 30Z are designated, A[1:0]=01, 10, and 11 is set. C[4:0] of 5 bits after A[1:0] designates a command content and a register address.

In FIG. 9 , as indicated by F1, R/W is 1, and thus an instruction for read is given, so that the microcontroller 80 issues a read command. As indicated by F2, A[1:0] is 00, and thus a common address is designated. An instruction for a command content and a register address is given by F3. Consequently, in a period T1, the X-axis angular velocity sensor device 30X outputs X-axis angular velocity data, in the next period T2, the Y-axis angular velocity sensor device 30Y outputs Y-axis angular velocity data, and, in the next period T3, the Z-axis angular velocity sensor device 30Z outputs Z-axis angular velocity data. The X-axis angular velocity data, the Y-axis angular velocity data, the Z-axis angular velocity data are angular velocity data which is fetched from the measurement circuits of the respective angular velocity sensor devices at a common synchronization timing of the synchronization signal SYC. As mentioned above, pieces of angular velocity data from the X-axis angular velocity sensor device 30X, the Y-axis angular velocity sensor device 30Y, and the Z-axis angular velocity sensor device 30Z can be continuously read in the first digital interface bus BS1 in FIG. 9 . This is realized by each angular velocity sensor device storing a transmission order thereof, the number of connected angular velocity sensor devices, and the number of bits of transmitted data.

FIG. 10 is a diagram illustrating a signal waveform example in the second digital interface bus BS2. The second digital interface bus BS2 also includes signal lines for the chip select signal XCS, the clock signal SCLK, the data input signal SDI, and the data output signal SDO. In FIG. 10 , the chip select signal XCS has an L level, and the acceleration sensor device 40 is selected as a chip. Thereafter, as indicated by F4, address setting for designating an address of the acceleration sensor device 40 is performed by the microcontroller 80 by using the data input signal SDI. The acceleration sensor device 40 outputs X-axis acceleration data in the period T1, outputs Y-axis acceleration data in the next period T2, and outputs Z-axis acceleration data in the next period T3. The X-axis acceleration data, the Y-axis acceleration data, and the Z-axis acceleration data are angular velocity data which is fetched from the measurement circuits of the respective acceleration sensor devices at a common synchronization timing of the synchronization signal SYC. As mentioned above, in the second digital interface bus BS2, the single acceleration sensor device 40 designated through the address setting indicated by F4 sequentially outputs the X-axis acceleration data, the Y-axis acceleration data, and the Z-axis acceleration data.

FIG. 11 illustrates a signal waveform example for explaining the continuation of continuous reading in the first digital interface bus BS1. In FIG. 11 , in the period T3, the Z-axis angular velocity sensor device 30Z outputs the Z-axis angular velocity data, and, in the next period T4, the X-axis angular velocity sensor device 30X outputs X-axis angular velocity data. In the next period T5, the Y-axis angular velocity sensor device 30Y outputs Y-axis angular velocity data, and, in the next period T6, the Z-axis angular velocity sensor device 30Z outputs Z-axis angular velocity data.

FIG. 12 is a diagram illustrating a signal waveform example in the second digital interface bus BS2 in a case where the first acceleration sensor device 40A and the second acceleration sensor device 40B are connected as illustrated in FIG. 8 . In the second digital interface bus BS2, continuous reading as in the first digital interface bus BS1 cannot be performed. Thus, the microcontroller 80 designates an address of the first acceleration sensor device 40A in address setting in F5. Consequently, the first acceleration sensor device 40A outputs X-axis acceleration data in a period TA1, outputs Y-axis acceleration data in the next period TA2, and outputs Z-axis acceleration data in the next period TA3. Next, the microcontroller 80 designates an address of the second acceleration sensor device 40B in address setting in F6. Consequently, the second acceleration sensor device 40B outputs X-axis acceleration data in a period TB1, outputs Y-axis acceleration data in the next period TB2, and outputs Z-axis acceleration data in the next period TB3.

In this case, in the present embodiment, the X-axis acceleration data output from the first acceleration sensor device 40A in the period TA1 and the Y-axis acceleration data output from the second acceleration sensor device 40B in the period TB1 are angular velocity data which is fetched from the measurement circuits of the respective acceleration sensor devices at a common synchronization timing. The Y-axis acceleration data in the period TA2 and the Y-axis acceleration data in the period TB2 are also pieces of acceleration data fetched at a common synchronization timing, and the Z-axis acceleration data in the period TA3 and the Z-axis acceleration data in the period TB3 are also pieces of acceleration data fetched at a common synchronization timing. Fetch of acceleration data at the common synchronization timing is realized by inputting the common synchronization signal SYC to the first acceleration sensor device 40A and the second acceleration sensor device 40B as illustrated in FIG. 8 . In the above-described way, in a case where an average value of X-axis acceleration data in the period TA1 and X-axis acceleration data in the period TB1 is obtained, it is possible to improve the accuracy of the average value. Similarly, in a case where an average value of Y-axis acceleration data in the period TA2 and Y-axis acceleration data in the period TB2, or an average value of Z-axis acceleration data in the period TA3 and Z-axis acceleration data in the period TB3 is obtained, it is possible to improve the accuracy of the average value.

In the present embodiment, for example, command systems are different from each other between the first digital interface bus BS1 and the second digital interface bus BS2, and thus communication methods for measurement data are also different from each other. For example, an angular velocity sensor device and an acceleration sensor device have different operation setting parameters or correction process parameters, and thus the types of commands or command parameters are different from each other. Thus, command systems are different from each other between the first digital interface bus BS1 and the second digital interface bus BS2.

As illustrated in FIG. 9 , in the angular velocity sensor devices, the angular velocity sensor device for each axis outputs angular velocity data about each axis. In other words, the X-axis angular velocity sensor device 30X outputs X-axis angular velocity data, the Y-axis angular velocity sensor device 30Y outputs Y-axis angular velocity data, and the Z-axis angular velocity sensor device 30Z outputs Z-axis angular velocity data. In contrast, in the acceleration sensor device, a single acceleration sensor device outputs acceleration data about a plurality of axes. In other words, the single acceleration sensor device 40 outputs X-axis acceleration data, Y-axis acceleration data, and Z-axis acceleration data. As mentioned above, communication methods are different from each other between the first digital interface bus BS1 and the second digital interface bus BS2.

In the angular velocity sensor devices, angular velocity data from a plurality of angular velocity sensor devices can be continuously read. In contrast, in the acceleration sensor device, acceleration data from a plurality of acceleration sensor devices cannot be continuously read. In other words, as illustrated in FIG. 12 , first, the microcontroller 80 designates an address of the first acceleration sensor device 40A, reads X-axis, Y-axis, and Z-axis acceleration data, and, then, designates an address of the second acceleration sensor device 40B, and reads X-axis, Y-axis, and Z-axis acceleration data. Regarding this content, communication methods are different from each other between the first digital interface bus BS1 and the second digital interface bus BS2. Even in the acceleration sensor device, there may be a modification in which pieces of data from a plurality of acceleration sensor devices can be continuously read.

In the sensor module 10, the plurality of sensor devices are provided to be separate from the microcontroller 80, and the data communication terminal of each sensor device is electrically connected to the data communication terminal of the microcontroller 80, but the sensor module 10 is not limited to such a configuration.

FIG. 13 illustrates another configuration example of the sensor module 10. The sensor module 10 in FIG. 13 includes the first sensor element 50X, the second sensor element 50Y, and an integrated circuit device 16. The first sensor element 50X and the second sensor element 50Y are sensor elements measuring physical quantities, and functions thereof the same as described above, and thus description thereof will be omitted. FIG. 13 illustrates an example in which the number of sensor elements is two, but the number of sensor elements may be three or more. For example, the sensor module 10 in FIG. 13 may include a first sensor element to an n-th sensor element (where n is an integer of 2 or greater).

The integrated circuit device 16 includes a measurement circuit 61, an interface circuit 71, the microcontroller 80, and the selection circuit 11. The integrated circuit device 16 is an IC chip implemented by semiconductor. A configuration of the integrated circuit device 16 is not limited to the configuration illustrated in FIG. 13 , and may be variously modified by omitting some constituent elements or adding other constituent elements. For example, the selection circuit 11 may be provided separately from the integrated circuit device 16.

The measurement circuit 61 receives signals from the first sensor element 50X and the second sensor element 50Y, and performs a measurement process. The measurement circuit 61 may include the first measurement circuit 60X which receives a signal from the first sensor element 50X and performs a measurement process, and the second measurement circuit 60Y which receives a signal from the second sensor element 50Y and performs a measurement process. Configurations of the first measurement circuit 60X and the second measurement circuit 60Y are the same as described above, for example, and thus a description thereof will be omitted.

The interface circuit 71 outputs medical measurement data from the measurement circuit 61. The interface circuit 71 may include the first interface circuit 70X which outputs measurement data from the first measurement circuit 60X, and the second interface circuit 70Y which outputs measurement data from the second measurement circuit 60Y. Configurations of the first interface circuit 70X and the second interface circuit 70Y are the same as described above, for example, and thus a description thereof will be omitted.

In a case where the number of sensor elements is three or more, and an n-th sensor element is provided, the measurement circuit 61 may include an n-th measurement circuit which receives a signal from the n-th sensor element and performs a measurement process, and the interface circuit 71 may include an n-th interface circuit which outputs n-th measurement data from the n-th measurement circuit.

The sensor module 10 includes the digital interface bus BS which electrically connects the interface circuit 71 to the microcontroller 80. For example, in a case where the interface circuit 71 includes the first interface circuit 70X and the second interface circuit 70Y, the digital interface bus BS may be a digital interface bus which electrically connects the first interface circuit 70X and the second interface circuit 70Y to the microcontroller 80. A configuration of the digital interface bus BS is the same as described above, for example, and thus a description thereof will be omitted.

The microcontroller 80 receives the measurement circuit 61 via the interface circuit 71. The microcontroller 80 includes, for example, the processing circuit 90, the signal processing circuit 92, the interruption controller 94, and the host interface circuit 96.

As described above, the signal processing circuit 92 performs a digital signal process such as a filtering process or a correction process on measurement data. The interruption controller 94 receives various interruption requests, and outputs various signals to the processing circuit 90 depending on a priority order and the interruption level. As described above, the host interface circuit 96 is a circuit which performs a digital interface process with the host device 210, and the host device 210 may access a data register of the register portion 91 via the host interface circuit 96, so as to read measurement data.

The processing circuit 90 is connected to the digital interface bus BS, and performs an interface process with the interface circuit 70 (the first interface circuit 70X or the second interface circuit 70Y) as a master. The processing circuit 90 includes the register portion 91 having various registers, and performs various calculation processes or control processes as described above. Specifically, as described above, the processing circuit 90 performs an interruption process corresponding to an interruption request, a temperature correction process on measurement data having undergone a filtering process in the signal processing circuit 92, and a process of generating the signal DRDY and outputting the signal DRDY to the host device 210.

The microcontroller 80 selects one of input of the external synchronization signal EXSYC or the synchronization signal SYC which is a signal based on the external synchronization signal EXSYC to the interface circuit 71, and input or output of a communication signal to or from the interface circuit 71. Specifically, for example, the processing circuit 90 of the microcontroller 80 outputs, to the selection circuit 11, the control signal CT for selecting one of input of the synchronization signal SYC to the interface circuit 71 and input or output of a communication signal to and from the interface circuit 71, based on a value of the control register of the register portion 91. The communication signal is a signal used for communication between the interface circuit 71 and the microcontroller 80, and corresponds to, for example, the chip select signal XCS, the clock signal SCLK, the data input signal SDI, and the data output signal SDO.

As described above, the selection circuit 11 includes the buffer 12, the resistor 13, the pull-up resistor 14, and the pull-down resistor 15. Connection relationships among the buffer 12, the resistor 13, the pull-up resistor 14, and the pull-down resistor 15 are the same manner as described in FIG. 1 . The selection circuit 11 selects whether or not the external synchronization signal EXSYC input to the buffer 12 is to be output as the synchronization signal SYC to a predetermined signal line included in the digital interface bus BS based on the control signal CT.

Specifically, when the control signal CT has an L level, the buffer 12 is operated in a through mode in which the input terminal is electrically connected to the output terminal, and thus outputs the external synchronization signal EXSYC input to the input terminal, from the output terminal. The external synchronization signal EXSYC having passed through the buffer 12 is input as the synchronization signal SYC to the interface circuit 71 (the first interface circuit 70X and the second interface circuit 70Y) via the digital interface bus BS. The synchronization signal SYC is input to the microcontroller 80 via the digital interface bus BS.

On the other hand, when the control signal CT has an H level, the input terminal is electrically disconnected from the output terminal, and thus the buffer 12 is brought into a Hi-Z output state. In a case where the buffer 12 is in the Hi-Z output state, the microcontroller 80 can perform data communication with the interface circuit 71 (the first interface circuit 70X and the second interface circuit 70Y) by making the chip select signal XCS active.

Since the predetermined signal line of the digital interface bus BS is a signal line via which the synchronization signal SYC is input to the microcontroller 80 and to which, for example, the microcontroller 80 outputs the data input signal SDI, the signal line may be used as an input signal line and an output signal line for the microcontroller 80. Thus, the processing circuit 90 of the microcontroller 80 sets the predetermined signal line as an output signal line before performing data communication with the interface circuit 71, and sets the predetermined signal line as an input signal line before outputting the control signal CT having an L level. For example, the processing circuit 90 may set the predetermined signal line as an input signal line or an output signal line by writing 0 or 1 into the control register of the register portion 91.

The synchronization signal SYC is the external synchronization signal EXSYC in FIG. 13 , but may be a signal based on the external synchronization signal EXSYC, and may be a signal generated by the synchronization signal output circuit 88 sampling the external synchronization signal EXSYC with a clock signal as described in FIG. 3 .

In the sensor module 10 in FIG. 13 , the interface circuit 71 (first interface circuit 70X) outputs first measurement data to the microcontroller 80 based on the synchronization signal SYC, and the interface circuit 71 (second interface circuit 70Y) outputs second measurement data to the microcontroller 80 based on the synchronization signal SYC. Therefore, the interface circuit 71 (the first interface circuit 70X and the second interface circuit 70Y) can acquire measurement data at an appropriate timing from the measurement circuit 61 (the first measurement circuit 60X and the second measurement circuit 60Y) by using the input synchronization signal SYC, and can output the measurement data to the microcontroller 80. Consequently, also in the sensor module 10 in FIG. 13 , in the same manner as in the sensor module 10 in FIG. 1 , it is possible to achieve high accuracy of information measured by using the sensor module 10.

In the sensor module 10 in FIG. 13 , the predetermined signal line of the digital interface bus BS is also used as a signal line through which the synchronization signal SYC propagates, and thus there is an advantage in the miniaturization of the sensor module 10.

2. Measurement System

FIG. 14 illustrates a configuration example of a measurement system 200 of the present embodiment. The measurement system 200 includes the sensor module 10 and the host device 210 electrically connected to the sensor module 10. The measurement system 200 may include a GPS reception unit 220, a GPS reception antenna 222 and an oscillator 230. In FIG. 14 , the sensor module 10 is used as a six-axis inertial measurement unit (IMU). The host device 210 may be implemented by various processors such as an MPU. The host device 210 may be implemented by an integrated circuit device such as an ASIC. The host device 210 includes a digital signal processor (DSP) 212 which performs a digital signal process, and a clock signal generation circuit 213 which generates a clock signal.

The GPS reception unit 220 receives a signal from a GPS satellite via the antenna 222. In other words, a satellite signal on which position information is superimposed is received as a GPS carrier wave. The GPS reception unit 220 is a GPS receiver, and may be implemented by an integrated circuit device including a GPS reception circuit. The host device 210 measures GPS positioning data indicating a position, a velocity, and an azimuth of a measurement target object such as a vehicle based on the signal received by the GPS reception unit 220. The position of the measurement target object is expressed by latitude, longitude, and altitude. The GPS positioning data includes status data indicating a reception state, a reception time, and the like. The host device 210 receives acceleration data and angular velocity data from the sensor module 10, and performs an inertial navigation calculation process on the data so as to obtain inertial navigation positioning data. The inertial navigation positioning data includes acceleration data and posture data of the measurement target object. The host device 210 calculates a position or the like of the measurement target object based on the obtained inertial navigation positioning data and GPS positioning data. In a case where the measurement target object is a vehicle such as an automobile, the host device 210 calculates a position where the vehicle travels on the ground. A process of calculating a position or a posture of the measurement target object may be realized through Karlman filter processing using the DSP 212.

The oscillator 230 generates an oscillation clock signal by using a resonator such as a quartz crystal resonator. The oscillator 230 is, for example, a temperature compensated crystal oscillator (TCXO). Alternatively, as the oscillator 230, an oven type oscillator (OCXO) provided with a thermostatic tank may be used. The clock signal generation circuit 213 generates various clock signals used in the host device 210 based on the oscillation clock signal from the oscillator 230. In this case, the clock signal generation circuit 213 generates a clock signal based on a time reference signal which is a signal acquired from a satellite positioning system such as a GPS. For example, the external synchronization signal EXSYC is generated as one of clock signals.

The host device 210 may obtain accurate absolute time information based on time information included in the satellite signal received by the GPS reception unit 220. The time information is information such as year, month, day, hour, minute, and second. The GPS reception unit 220 outputs a PPS signal in which a pulse is generated every second as the time reference signal. The clock signal generation circuit 213 is configured with a PLL circuit which operates based on the oscillation clock signal from the oscillator 230, and the PPS signal is input to the PLL circuit as a reference signal for clock synchronization. The PLL circuit generates a clock signal synchronized with the PPS signal which is the time reference signal. The host device 210 outputs the external synchronization signal EXSYC synchronized with the time reference signal to the sensor module 10.

As mentioned above, in the present embodiment, the external synchronization signal EXSYC is generated based on the time reference signal. Consequently, the sensor module 10 can acquire measurement data in a sensor device by using the external synchronization signal EXSYC generated based on the time reference signal. In other words, the sensor module 10 can acquire measurement data from a measurement circuit of the sensor device at a timing synchronized with an accurate time point by using the external synchronization signal EXSYC generated based on the time reference signal. Therefore, the sensor module 10 can output the measurement data acquired at an appropriately timing synchronized with the accurate time point to the host device 210, and can thus achieve high accuracy of information measured by using the sensor module 10.

For example, the host device 210 can acquire accurate absolute time information by using the satellite signal received by the GPS reception unit 220. Therefore, an absolute time point of each synchronization timing of the external synchronization signal EXSYC can also be specified. The measurement data acquired at the synchronization timing of the external synchronization signal EXSYC is output from the sensor module 10. Since a delay time from an acquisition timing for measurement data in a sensor device to a timing at which the measurement data is input to the host device 210 is a delay time due to digital processing, the host device 210 can specify the number of clocks corresponding to a length of the delay time. Therefore, the host device 210 can specify the time at which measurement data such as acceleration data or angular velocity data which is input from the sensor module 10 is acquired. As described above, the host device 210 calculates a position or the like of the measurement target object based on the GPS positioning data obtained by using the satellite signal and the inertial navigation positioning data obtained by using the measurement data from the sensor module 10. Therefore, the host device 210 can specify an absolute time point of an acquisition timing for measurement data such as acceleration data or angular velocity data, and can thus accurately calculate a position or the like of the measurement target object.

In the present embodiment, the time reference signal is a signal acquired from, for example, a satellite positioning system. For example, the time reference signal is a PPS signal acquired from the satellite positioning system. In the above-described way, a time reference signal is acquired by effectively using the satellite positioning system, and measurement data in a sensor device can be acquired by using the external synchronization signal EXSYC generated based on the acquired time reference signal.

In the above description, a global positioning system (GPS) has been described as the satellite positioning system, but the measurement system 200 may use other global navigation satellite systems (GNSS) as the satellite positioning system. For example, the measurement system 200 may use one, or two or more satellite positioning systems such as a European geostationary-satellite navigation overlay service (EGNOS), a quasi zenith satellite system (QZSS), a global navigation satellite system (GLONASS), GALILEO, and a Beidou navigation satellite system (BeiDou). As at least one of the satellite positioning systems, the measurement system 200 may use a satellite-based augmentation system (SBAS) such as a wide area augmentation system (WAAS) or a European geostationary-satellite navigation overlay service (EGNOS). The time reference signal is not limited to a signal acquired from the satellite positioning system. For example, the measurement system 200 may generate the time reference signal by using a highly accurate oscillator such as an atomic oscillator, and may generate the time reference signal by acquiring an absolute time point by using a network.

3. Specific Examples of Sensor Module

FIG. 15 is an exploded perspective view illustrating a specific example of the sensor module 10. The sensor module 10 in FIG. 15 includes the circuit substrate 100, an inner case 120, an annular buffer material 130, and an outer case 140, so as to configure a sensor unit. The sensor module 10 has a configuration in which the circuit substrate 100 is mounted inside the outer case 140 via the annular buffer material 130. Sensor devices such as angular velocity sensor devices and acceleration sensor devices are mounted on the circuit substrate 100.

The sensor module 10 is a rectangular parallelepiped of which a planar shape is a square shape, and screw holes 142 and 144 are formed near two vertexes located in the diagonal direction of the square. The sensor module 10 is used in a state of being fixed to an attachment surface of a measurement target object such as an automobile by inserting two screws into the screw holes 142 and 144. An opening 122 is formed on a surface of the sensor module 10 in a top view. The plug type connector 110 is disposed inside the opening 122. The connector 110 has a plurality of arranged pins. A socket type connector is connected to the connector 110, and transmission and reception of electric signals such as the supply of power to the sensor module 10 or output of measurement data measured by the sensor module 10 are performed. The outer case 140 is a pedestal obtained, for example, by cutting out aluminum. An outer shape of the outer case 140 is a rectangular parallelepiped shape of which a planar shape is a square shape in the same manner as the entire shape of the sensor module 10. However, an outer planar shape of the outer case 140 may be, for example, a polygonal shape such as a hexagonal shape or an octagonal shape, a corner of a vertex portion of the polygonal shape may be chamfered, each side thereof may be curved, and an outer shape thereof may be a circular shape.

In FIG. 15 , the depression 121 is provided on a bottom surface side of the inner case 120. A sensor device group including an angular velocity sensor device and an acceleration sensor device is disposed in a region overlapping the depression 121 in a plan view (a plan view in the negative direction of the Z axis) viewed from a thickness direction of the circuit substrate 100. A filling member fills a space formed by the circuit substrate 100 and the depression 121, and is solidified. Consequently, a part or the whole of the circuit substrate 100 and the sensor device group is covered with the filling member, and thus a resonance frequency can be shifted to be excluded from a band of noise resonance from the outside.

4. Angular Velocity Sensor Device

FIG. 16 illustrates a detailed configuration example of an angular velocity sensor device 30. The angular velocity sensor device 30 includes a vibrator 56, a drive circuit 58, the measurement circuit 60, the processing circuit 66, and the interface circuit 70. The drive circuit 58 may include an amplification circuit which receives a feedback signal DG from the vibrator 56 and amplifies the signal, an AGC circuit which performs automatic gain control, or an output circuit which outputs a drive signal DS to the vibrator 56. For example, the AGC circuit automatically adjusts a gain in a variable manner such that the amplitude of the feedback signal DG from the vibrator 56 is constant. The output circuit outputs, for example, the drive signal DS of a rectangular wave to the vibrator 56. The measurement circuit 60 may include an amplification circuit, a synchronous detecting circuit, an A/D conversion circuit, and the like. The amplification circuit receives measurement signals S1 and S2 from the vibrator 56, and performs charge-voltage conversion or amplification of the measurement signals S1 and S2 which are differential signals. The synchronous detecting circuit performs synchronous detection for extracting a desired wave by using a synchronization signal from the drive circuit 58. The A/D conversion circuit converts an analog measurement signal having undergone synchronous detection into digital measurement data which is then output to the processing circuit 66. The processing circuit 66 performs various processes such as zero point correction, sensitivity adjustment, a filtering process, and temperature correction on the measurement data, and outputs the measurement data having undergone the processes to the interface circuit 70.

In FIG. 16 , a double-T type vibrator is used as the vibrator 56. As the vibrator 56, a tuning fork type or H type vibrator may be used. The vibrator 56 includes drive arms 38A, 38B, 38C, and 38D, detection arms 39A and 39B, a base portion 31, and connection arms 32A and 32B. The detection arms 39A and 39B respectively extend in a +y axis direction and a −y axis direction from the rectangular base portion 31. The connection arms 32A and 32B respectively extend in a +x axis direction and a −x axis direction from the base portion 31. The drive arms 38A and 38B respectively extend in the +y axis direction and the −y axis direction from a distal end part of the connection arm 32A, and drive arms 38C and 38D respectively extend in the +y axis direction and the −y axis direction from a distal end part of the connection arm 32B. Frequency adjustment weight parts are provided on distal end sides of the drive arms 38A, 38B, 38C, and 38D and the detection arms 39A and 39B. In a case where a z axis is set in a thickness direction of the vibrator 56, the vibrator 56 measures an angular velocity about the z axis.

Drive electrodes 33 are formed on upper surfaces and lower surfaces of the drive arms 38A and 38B, and drive electrodes 34 are formed on right side surfaces and left side surfaces of the drive arms 38A and 38B. The drive electrodes 34 are formed on upper surfaces and lower surfaces of the drive arms 38C and 38D, and the drive electrodes 33 are formed on right side surfaces and left side surfaces of the drive arms 38C and 38D. The drive signal DS from the drive circuit 58 is supplied to the drive electrodes 33, and the feedback signal DG from the drive electrodes 34 is input to the drive circuit 58. Detection electrodes 35 are formed on an upper surface and a lower surface of the detection arm 39A, and ground electrodes 37 are formed on a right side surface and a left side surface of the detection arm 39A. Detection electrodes 36 are formed on an upper surface and a lower surface of the detection arm 39B, and the ground electrodes 37 are formed on a right side surface and a left side surface of the detection arm 39B. The detection signals S1 and S2 from the detection electrodes 35 and 36 are input to the measurement circuit 60.

Next, a description will be made of an operation of the angular velocity sensor device 30. In a case where the drive circuit 58 applies the drive signal DS to the drive electrodes 33, the drive arms 38A, 38B, 38C, and 38D perform flexural vibration as indicated by arrows C1 in FIG. 16 due to an inverse piezoelectric effect. For example, a vibration attitude indicated by a solid arrow and a vibration attitude indicated by a dotted arrow are repeated at a predetermined frequency. In other words, flexural vibration is performed in which the distal ends of the drive arms 38A and 38C repeatedly come close to and become distant from each other, and the distal ends of the drive arms 38B and 38D repeatedly come close to and become distant from each other. In this case, since the drive arms 38A and 38B and the drive arms 38C and 38D perform linearly symmetric vibration with respect to the x axis passing through the central position of the base portion 31, the base portion 31, the connection arms 32A and 32B, and the detection arms 39A and 39B scarcely vibrate.

In this state, in a case where an angular velocity is applied to the vibrator 56 with the z axis as a rotation axis, the drive arms 38A, 38B, 38C, and 38D vibrate as indicated by arrows C2 due to the Coriolis force. In other words, the Coriolis force in the direction of the arrow C2 which is orthogonal to the direction of the arrow C1 and the direction of the z axis acts on the drive arms 38A, 38B, 38C, and 38D, and thus a vibration component in the direction of the arrow C2 is generated. The vibration in the direction of the arrow C2 is transferred to the base portion 31 via the connection arms 32A and 32B, and thus the detection arms 39A and 39B perform flexural vibration in the direction of the arrow C3. Electric charge signals generated due to a piezoelectric effect caused by the flexural vibration of the detection arms 39A and 39B are input to the measurement circuit 60 as the detection signals S1 and S2, and thus an angular velocity about the z axis is measured.

5. Electronic Apparatus

FIG. 17 is a block diagram illustrating a configuration example of an electronic apparatus 300 of the present embodiment. The electronic apparatus 300 includes the sensor module 10 of the present embodiment, and a processing section 320 which performs a process based on an output signal from the sensor module 10. The electronic apparatus 300 may include a communication section 310, an operation section 330, a display section 340, a storage section 350, and an antenna 312.

The communication section 310 is, for example, a wireless circuit, and performs a process of receiving data from the outside or transmitting data to the outside via the antenna 312. The processing section 320 performs a control process on the electronic apparatus 300, or performs various digital processes on data transmitted and received via the communication section 310. The processing section 320 performs a process based on an output signal from the sensor module 10. Specifically, the processing section 320 performs a signal process such as a correction process or a filtering process on an output signal (output data) such as measurement data in the sensor module 10, or performs various control processes on the electronic apparatus 300 based on the output signal. A function of the processing section 320 may be realized by a processor such as an MPU or a CPU. The operation section 330 is used for a user to perform an input operation, and may be implemented by an operation button or a touch panel display. The display section 340 displays various pieces of information, and may be implemented by a liquid crystal display or an organic EL display. The storage section 350 stores data, and a function thereof may be realized by a semiconductor memory such as a RAM or a ROM.

The electronic apparatus 300 of the present embodiment is applicable to, for example, a video associated apparatus such as a digital camera or a video camera, an on-vehicle apparatus, a wearable apparatus such as a head mounted display or a timepiece associated apparatus, an ink jet ejection apparatus, a robot, a personal computer, a portable information terminal, a printing apparatus, or a projection apparatus. The on-vehicle apparatus is, for example, a car navigation apparatus or an apparatus for automatic driving. The timepiece associated apparatus is a timepiece or a smart timepiece. The ink jet ejection apparatus is, for example, an ink jet printer. The portable information terminal is, for example, a smart phone, a mobile phone, a portable game machine, a notebook PC, or a tablet terminal. The electronic apparatus 300 of the present embodiment is applicable to an electronic organizer, an electronic dictionary, an electronic calculator, a word processor, a workstation, a videophone, a security television monitor, electronic binoculars, a POS terminal, a medical apparatus, a fish-finder, a measurement apparatus, an apparatus for mobile terminal base station, meters and gauges, a flight simulator, and a network server. The medical apparatus is, for example, an electronic thermometer, a sphygmomanometer, a blood glucose monitoring system, an electrocardiographic apparatus, an ultrasonic diagnostic apparatus, or an electronic endoscope. The meters and gauges are, for example, meters and gauges of vehicles, aircrafts, and ships.

FIG. 18 is a plan view illustrating a wristwatch type activity meter 400 which is a portable electronic apparatus, and FIG. 19 is a block diagram illustrating a configuration example of the activity meter 400. The activity meter 400 is mounted on a part such as a user's wrist via a band 401. The activity meter 400 which is an activity tracker is provided with a display section 402 performing digital display, and can perform wireless communication based on Bluetooth (registered trademark) or Wi-Fi (registered trademark).

As illustrated in FIGS. 18 and 19 , the activity meter 400 includes a case 403 in which the sensor module 10 is accommodated, a processing section 410 which is accommodated in the case 403 and performs a process based on an output signal from the sensor module 10, the display section 402 which is accommodated in the case 403, and a light transmissive cover 404 which closes an opening of the case 403. A bezel 405 is provided outside the light transmissive cover 404, and a plurality of operation buttons 406 and 407 are provided on a side surface of the case 403. The sensor module 10 is provided with an acceleration sensor 414 measuring three-axis accelerations, and an angular velocity sensor 415 measuring three-axis angular velocities as sensor devices. The sensor module 10 may be provided with a geomagnetic sensor 412, a pressure sensor 413, a pulse sensor 416, or a temperature sensor 417 as a sensor device.

The display section 402 displays, for example, position information or a movement amount obtained by using a GPS sensor 411 or the geomagnetic sensor 412, motion information such as a motion amount obtained by using the acceleration sensor 414 or the angular velocity sensor 415, biological information such as a pulse rate obtained by using the pulse sensor 416, or time information such as the current time, according to various measurement modes. An environment temperature obtained by using a temperature sensor 417 may be displayed. A communication section 422 performs communication with an information terminal such as a user terminal. The processing section 410 which is a processor is implemented by an MPU, a DSP, or an ASIC. The processing section 410 performs various processes based on a program stored in a storage section 420, and information which is input from an operation section 418 such as the operation buttons 406 and 407. As processes performed by the processing section 410, there are processes based on output signals from the GPS sensor 411, the geomagnetic sensor 412, the pressure sensor 413, the acceleration sensor 414, the angular velocity sensor 415, the pulse sensor 416, the temperature sensor 417, and a clocking section 419. The processing section 410 may perform a display process of displaying an image on the display section 402, a sound output process of outputting sounds from a sound output section 421, a communication process of performing communication with an information terminal via the communication section 422, and a power control process of supplying power to each section from a battery 423.

According to the activity meter 400 of the present embodiment having the above-described configuration, it is possible to achieve the effect of the sensor module 10 and thus to realize high reliability. The activity meter 400 includes the GPS sensor 411 and can thus measure a movement distance or a movement path of a user, and thus it is possible to provide the activity meter 400 with high convenience. The activity meter 400 is widely applicable to a running watch, a runner's watch, an outdoor watch, and a GPS watch with a GPS.

6. Vehicle

A vehicle of the present embodiment includes the sensor module 10 of the embodiment, and a control device which performs control of a posture of the vehicle based on information regarding a posture of the vehicle obtained through a process based on an output signal from the sensor module 10.

FIG. 20 illustrates a vehicle 500 using the sensor module 10 of the present embodiment. FIG. 21 is a block diagram illustrating a configuration example of the vehicle 500. As illustrated in FIG. 20 , the vehicle 500 has a car body 502 and car wheels 504. The vehicle 500 is provided with a positioning apparatus 510, and is provided with a control device 570 which performs vehicle control therein. As illustrated in FIG. 21 , the vehicle 500 includes a drive mechanism 580 such as an engine or a motor, a braking mechanism 582 such as a disk brake or a drum brake, and a steering mechanism 584 implemented by a steering wheel or a steering gear box. As mentioned above, the vehicle 500 is an apparatus or equipment which includes the drive mechanism 580, the braking mechanism 582, or the steering mechanism 584, and moves on the ground, in the air, and in the sea. For example, the vehicle 500 is a four-wheeled vehicle such as an agricultural machine.

The positioning apparatus 510 is attached to the vehicle 500, and performs positioning of the vehicle 500. The positioning apparatus 510 includes the sensor module 10, a GPS reception section 520, a GPS reception antenna 522, and a host device 530. The host device 530 includes a position information acquisition section 532, a position combination section 534, a calculation processing section 536, and a processing section 538. The sensor module 10 which is an IMU includes a three-axis acceleration sensor and a three-axis angular velocity sensor. The calculation processing section 536 receives acceleration data and angular velocity data from the acceleration sensors and the angular velocity sensors, and performs an inertial navigation calculation process on the data so as to output inertial navigation positioning data. The inertial navigation positioning data indicates acceleration and a posture of the vehicle 500.

The GPS reception section 520 receives a signal from a GPS satellite via the antenna 522. The position information acquisition section 532 outputs GPS positioning data indicating a position, velocity, and an azimuth of the vehicle 500 with the positioning apparatus 510 based on the signal received by the GPS reception section 520. The position combination section 534 calculates a position where the vehicle 500 is traveling on the ground based on the inertial navigation positioning data output from the calculation processing section 536 and the GPS positioning data output from the position information acquisition section 532. For example, in a case where positions of the vehicle 500 included in the GPS positioning data are the same as each other, but postures of the vehicle 500 are different from each other due to the influence of an inclination (0) of the ground, the vehicle 500 travels at different positions on the ground, as illustrated in FIG. 20 . Thus, an accurate position of the vehicle 500 cannot be calculated by using only the GPS positioning data. Therefore, the position combination section 534 calculates a position where the vehicle 500 travels on the ground by using data regarding a posture of the vehicle 500 in the inertial navigation positioning data. Position data output from the position combination section 534 is subjected to a predetermined process in the processing section 538, and is displayed on the display section 550 as a positioning result. The position data may be transmitted to an external apparatus via the communication section 560.

The control device 570 controls the drive mechanism 580, the braking mechanism 582, and the steering mechanism 584 of the vehicle 500. The control device 570 is a controller for vehicle control, and may be implemented by, for example, a plurality of control units. The control device 570 includes a vehicle control section 572 which is a control unit performing vehicle control, an automatic driving control section 574 which is a control unit performing automatic driving control, and a storage section 576 implemented by a semiconductor memory. A monitoring device 578 is a device monitoring objects such as a peripheral obstacle of the vehicle 500, and is implemented by a periphery monitoring camera, a millimeter wave radar, or a sonar.

As illustrated in FIG. 21 , the vehicle 500 of the present embodiment includes the sensor module 10 and the control device 570. The control device 570 controls a posture of the vehicle 500 based on posture information of the vehicle 500 which is obtained through a process based on an output signal from the sensor module 10. For example, the host device 530 performs the above-described various processes based on output signals including measurement data from the sensor module 10, so as to obtain position information or posture information of the vehicle 500. For example, the host device 530 may obtain the position information of the vehicle 500 based on the above-described GPS positioning data and inertial navigation positioning data. The host device 530 may obtain posture information of the vehicle 500 based on, for example, angular velocity data included in the inertial navigation positioning data. The posture information of the vehicle 500 is information regarding rotational motion corresponding to rolling, pitching, and yawing, and may be indicated by a roll angle, a pitch angle, and a yaw angle. The control device 570 controls, for example, a posture of the vehicle 500 based on the posture information of the vehicle 500 obtained through the process in the host device 530. This control is performed by, for example, vehicle control section 572. The posture control may be realized, for example, by the control device 570 controlling the steering mechanism 584. Alternatively, in control of stabilizing a posture of the vehicle 500, such as slip control, the control device 570 may control the drive mechanism 580 or the braking mechanism 582. According to the present embodiment, posture information obtained by using an output signal from the sensor module 10 can be obtained with high accuracy, and thus it is possible to realize appropriate posture control of the vehicle 500.

In the present embodiment, the control device 570 controls at least one of acceleration, braking, and steering of the vehicle 500 based on position information and posture information of the vehicle 500 obtained through processes based on output signals from the sensor module 10. For example, the control device 570 controls at least one of the drive mechanism 580, the braking mechanism 582, and the steering mechanism 584 based on the position information and the posture information of the vehicle 500. Consequently, for example, it is possible to realize automatic driving control of the vehicle 500 by using the automatic driving control section 574. In the automatic driving control, not only the position information and the posture information of the vehicle 500 but also a monitoring result of a peripheral object using the monitoring device 578, or map information or traveling route information stored in the storage section 576 may be used. The control device 570 switches between execution and non-execution of automatic driving of the vehicle 500 based on a monitoring result of an output signal from the sensor module 10. For example, the host device 530 monitors an output signal such as measurement data from the sensor module 10. For example, in a case where a reduction in measurement accuracy or sensing abnormality in the sensor module 10 is detected based on the monitoring result, the control device 570 switches execution of automatic driving to non-execution of the automatic driving. For example, in the automatic driving, at least one of acceleration, braking, and steering of the vehicle 500 is automatically controlled. On the other hand, in the non-execution of the automatic control, automatic driving of acceleration, braking, and steering is not performed. In the above-described way, it is possible to perform support with higher reliability on traveling of the vehicle 500 performing automatic driving. Switching between automation levels may be performed based on a monitoring result of an output signal from the sensor module 10.

FIG. 22 illustrates another vehicle 600 using the sensor module 10. FIG. 23 is a block diagram illustrating a configuration example of the vehicle 600. The sensor module 10 of the embodiment can be effectively used for posture control or the like of a construction machine, and FIGS. 22 and 23 illustrate a hydraulic shovel which is an example of a construction machine as the vehicle 600.

As illustrated in FIG. 22 , the vehicle 600 has a vehicle body configured with a lower traveling body 612 and an upper turning body 611 which is turnably mounted on the lower traveling body 612, and is provided with a work machine 620 configured with a plurality of members which are vertically rotatable on a front portion side of the upper turning body 611. A driver's seat (not illustrated) is provided in the upper turning body 611, and operation devices (not illustrated) operating each member configuring the work machine 620 are provided on the driver's seat. The upper turning body 611 is provided with a sensor module 10 d functioning as an inclination sensor measuring an inclined angle of the upper turning body 611.

The work machine 620 includes, as the plurality of members, a boom 613 which is attached to the front portion side of the upper turning body 611 in a manner of being able to move up and down, an arm 614 which is attached to a distal end side of the boom 613 in a manner of being able to move up and down, a bucket link 616 which is rotatably attached to a distal end side of the arm 614, a bucket 615 which is rotatably attached to distal end sides of the arm 614 and the bucket link 616, a boom cylinder 617 which drives the boom 613, an arm cylinder 618 which drives the arm 614, and a bucket cylinder 619 which drives the bucket 615 via the bucket link 616.

A basal end side of the boom 613 is vertically rotatably supported at the upper turning body 611, and the boom 613 is rotationally driven relative to the upper turning body 611 due to expansion and contraction of the boom cylinder 617. The sensor module 10 c which functions as an inertial sensor detecting a movement state of the boom 613 is disposed in the boom 613.

A one end side of the arm 614 is rotatably supported on the distal end side of the boom 613, and the arm 614 is rotationally driven relative to the boom 613 due to expansion and contraction of the arm cylinder 618. The sensor module 10 b which functions as an inertial sensor detecting a movement state of the arm 614 is disposed in the arm 614.

The bucket link 616 and the bucket 615 are rotatably supported on the distal end side of the arm 614, the bucket link 616 is rotationally driven relative to the arm 614 due to expansion and contraction of the bucket cylinder 619, and the bucket 615 is rotationally driven relative to the arm 614 in conjunction therewith. The sensor module 10 a which functions as an inertial sensor detecting a movement state of the bucket link 616 is disposed in the bucket link 616.

Here, the sensor module 10 described in the embodiment may be used as the sensor modules 10 a, 10 b, 10 c, and 10 d. The sensor modules 10 a, 10 b, 10 c, and 10 d can measure at least one of angular velocity and acceleration applied to each member of the work machine 620 or the upper turning body 611. As illustrated in FIG. 23 , the sensor modules 10 a, 10 b, and 10 c are connected in series to each other, and may transmit a measurement signal to a control device 631. As mentioned above, the sensor modules 10 a, 10 b, and 10 c are connected in series to each other, and thus the number of wires for transmitting a measurement signal in a movable region can be reduced such that a compact wiring structure can be obtained. With the compact wiring structure, it becomes easier to select a method of laying wires, and thus it is possible to reduce the occurrence of deterioration in a wire or damage thereon.

As illustrated in FIG. 22 , the vehicle 600 is provided with the control device 631 which calculates an inclined angle of the upper turning body 611 or positional postures of the boom 613, the arm 614, and the bucket 615 configuring the work machine 620. The control device 631 controls a posture of the vehicle 600 based on posture information of the vehicle 600 which is obtained through processes based on output signals from the sensor modules 10 a, 10 b, 10 c, and 10 d. Specifically, the control device 631 receives various measurement signals from the respective sensor modules 10 a, 10 b, 10 c, and 10 d, and calculates positional postures (posture angles) of the boom 613, the arm 614, and the bucket 615 or an inclination state of the upper turning body 611 based on the various measurement signals. Among positional posture signals including the calculated posture angles of the boom 613, the arm 614, and the bucket 615 or an inclination signal including the calculated posture angle of the upper turning body 611, for example, the positional posture signal for the bucket 615 is used for display on a monitor device (not illustrated) in the driver's seat or for feedback information for controlling an operation of the work machine 620 or the upper turning body 611.

As a construction machine using the sensor module 10 of the embodiment, there is not only the exemplified hydraulic shovel (a jumbo, a backhoe, or a power shovel), but also, for example, a rough terrain crane (crane vehicle), a bulldozer, an excavator, a loading machine, a wheel loader, and a vehicle for high lift work (lift vehicle).

According to the present embodiment, posture information obtained based on an output signal from the sensor module 10 (10 a, 10 b, 10 c, and 10 d) can be obtained with high accuracy, and thus it is possible to realize appropriate posture control of the vehicle 600. Since the vehicle 600 is provided with the compact sensor module 10, for example, it is possible to provide a construction machine in which a plurality of sensor elements can be disposed to be compact through serial connection (multi-connection) or routing of a cable connecting the sensor modules 10 provided in respective locations in series to each other can be made compact at each an installation location of the sensor module 10 even in a considerably restricted narrow region such as the bucket link 616.

In the present embodiment, as a vehicle using the sensor module 10, a four-wheeled vehicle such as an agricultural machine, or a construction machine has been described as an example, but, in addition thereto, there are a motorcycle, a bicycle, a train, an aircraft, a biped robot, a radio controlled plane, a radio controlled helicopter, a remote controlled or autonomous flying body such as a drone, a rocket, or an artificial satellite, a ship, and an automatic guided vehicle (AGV).

The present disclosure is not limited to the present embodiment, and may be variously modified within the scope of the spirit of the present disclosure.

The embodiments and modification examples are only examples, and there is no limitation thereto. For example, each embodiment and each modification example may be combined with each other as appropriate.

The present disclosure includes a configuration (for example, a configuration which is identical in function, method, and result, or a configuration which is identical in purpose and effect) which is substantially the same as the configuration described in the embodiment. The present disclosure includes a configuration with which an inessential portion of the configuration described in the embodiment is replaced. The present disclosure includes a configuration achieving the same advantageous effect as that of the configuration described in the embodiment or a configuration capable of achieving the same object. The present disclosure includes a configuration to which a well-known technique is added to the configuration described in the embodiment. 

What is claimed is:
 1. A sensor module comprising: a synchronization terminal to which a synchronization signal is input; a first sensor element; a first measurement circuit that processes a signal output from the first sensor element to obtain first measurement data; a first register that fetches the first measurement data from the first measurement circuit at synchronization timing of the synchronization signal input via the synchronization terminal; a second sensor element; a second measurement circuit that processes a signal output from the second sensor element to obtain second measurement data; a second register that fetches the second measurement data from the second measurement circuit at synchronization timing of the synchronization signal input via the synchronization terminal; and a microcontroller that acquires the first measurement data read from the first register and the second measurement data read from the second register.
 2. The sensor module according to claim 1, wherein the microcontroller acquires the first measurement data fetched by the first register and the second measurement data fetched by the second register when the microcontroller issues a command.
 3. The sensor module according to claim 2, wherein when signal process of the first detection data and the second detection data fetched at the synchronization timing of the synchronization signal is finished, the microcontroller output a signal indicating completion of preparation of measurement data to a host device.
 4. The sensor module according to claim 1, wherein the first measurement circuit and the second measurement circuit having an A/D conversion circuit which converts an analog signal from the analog circuit into digital data, and the first detection data and the second detection data are the digital data.
 5. The sensor module according to claim 1, wherein the microcontroller includes an interruption controller, and the synchronization signal is input to the interruption controller as one of interruption request signals.
 6. An electronic apparatus comprising: the sensor module according to claim 1; and a processor that performs a process based on an output signal from the sensor module. 